1 Introduction
The first systematic work on the representation theory of the
$0$
-Hecke algebras was made by Norton [Reference Norton25], who completely classified all projective indecomposable modules and simple modules, up to isomorphism, for all
$0$
-Hecke algebras of finite type. In the case where
$H_n(0)$
, the
$0$
-Hecke algebra of type
$A_{n-1}$
, they are naturally parametrised by compositions of n. For each composition
$\alpha $
of n, let us denote by
$\mathbf {P}_{\alpha }$
and
$\mathbf {F}_{\alpha }$
the projective indecomposable module and the simple module corresponding
$\alpha $
, respectively (see Subsection 2.3). These modules were again studied intensively in the 2000s (for instance, see [Reference Denton13, Reference Hivert, Novelli and Thibon19, Reference Huang20]). In particular, Huang [Reference Huang20] studied the induced modules
$\mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}}$
of projective indecomposable modules by using the combinatorial objects called standard ribbon tableaux, where
${\boldsymbol {\unicode{x3b1} }}$
in bold-face ranges over the set of generalised compositions.
In [Reference Duchamp, Krob, Leclerc and Thibon15, Reference Krob and Thibon22], it was shown that the representation theory of the 0-Hecke algebras of type A has a deep connection to the ring
$\mathrm {QSym}$
of quasisymmetric functions. Letting
$\mathcal {G}_0(H_n(0))$
be the Grothendieck group of the category of finitely generated
$H_n(0)$
-modules, their direct sum over all
$n\ge 0$
endowed with the induction product is isomorphic to
$\mathrm {QSym}$
via the quasisymmetric characteristic
$$ \begin{align*} \mathrm{ch} : \bigoplus_{n \ge 0} \mathcal{G}_0(H_n(0)) \rightarrow \mathrm{QSym}, \quad [\mathbf{F}_{\alpha}] \mapsto F_{\alpha}. \end{align*} $$
Here, for a composition
$\alpha $
of n,
$[\mathbf {F}_{\alpha }]$
is the equivalence class of
$\mathbf {F}_{\alpha }$
inside
$\mathcal {G}_0(H_n(0))$
, and
$F_{\alpha }$
is the fundamental quasisymmetric function attached to
$\alpha $
(for more information; see Subsection 2.2).
Suppose that
$\alpha $
ranges over the set of all compositions of n. In the mid-2010s, Berg, Bergeron, Saliola, Serrano and Zabrocki [Reference Berg, Bergeron, Saliola, Serrano and Zabrocki4] introduced the immaculate functions
$\mathfrak {S}_{\alpha }$
by applying noncommutative Bernstein operators to the constant power series
$1$
, the identity of the ring
$\mathrm {NSym}$
of noncommutative symmetric functions. These functions form a basis of
$\mathrm {NSym}$
. Then the authors defined the dual immaculate function
$\mathfrak {S}^{\ast }_{\alpha }$
as the quasisymmetric function dual to
$\mathfrak {S}_{\alpha }$
under the appropriate pairing between
$\mathrm {QSym}$
and
$\mathrm {NSym}$
; thus
$\mathfrak {S}^{\ast }_{\alpha }$
s also form a basis of
$\mathrm {QSym}$
. Due to their nice properties, the immaculate and dual immaculate functions have since drawn the attention of many mathematicians (see [Reference Berg, Bergeron, Saliola, Serrano and Zabrocki6, Reference Bergeron, Sánchez-Ortega and Zabrocki7, Reference Campbell10, Reference Campbell11, Reference Gao and Yang17, Reference Grinberg18, Reference Mason and Searles24]). In a subsequent paper [Reference Berg, Bergeron, Saliola, Serrano and Zabrocki5], the same authors successfully construct a cyclic indecomposable
$H_n(0)$
-module
$\mathcal {V}_{\alpha }$
with
$\mathrm {ch}(\mathcal {V}_{\alpha })=\mathfrak {S}^{\ast }_{\alpha }$
by using combinatorial objects called standard immaculate tableaux. Although several notable properties have recently been revealed in [Reference Choi, Kim, Nam and Oh12, Reference Jung, Kim, Lee and Oh21], the structure of
$\mathcal {V}_{\alpha }$
is not yet well known, especially compared to
$\mathfrak {S}^{\ast }_{\alpha }$
.
The studies of the
$0$
-Hecke algebras from the homological viewpoint can be found in [Reference Cabanes9, Reference Duchamp, Hivert and Thibon14, Reference Fayers16]. For type A, Duchamp, Hivert and Thibon [Reference Duchamp, Hivert and Thibon14, Section 4] construct all nonisomorphic 2-dimensional indecomposable modules and use this result to calculate
$\mathrm {Ext}^1_{H_n(0)}(\mathbf {F}_{\alpha },\mathbf {F}_{\beta })$
for all compositions
$\alpha , \beta $
of n.
Moreover, when
$n \le 4$
, they show that its Poincaré series is given by the
$(\alpha ,\beta )$
entry of the inverse of
$(-q)$
-Cartan matrix. For all finite types, Fayers [Reference Fayers16, Section 5] shows that
$\dim \mathrm {Ext}^1_{\mathcal {\bullet }}(M,N) =1$
or
$0$
for all simple modules M and N. He also classifies when the dimension equals
$1$
. However, to the best knowledge of the authors, little is known about Ext-groups other than simple (and projective) modules.
In this paper, we study homological properties of
$\mathcal {V}_{\alpha }$
s. To be precise, we explicitly describe a minimal projective presentation and a minimal injective presentation of
$\mathcal {V}_{\alpha }$
. By employing these presentations, we calculate
$$\begin{align*}\mathrm{Ext}_{H_n(0)}^1(\mathcal{V}_{\alpha}, \mathbf{F}_{\beta}) \quad \text{and} \quad \mathrm{Ext}_{H_n(0)}^1(\mathbf{F}_{\beta}, \mathcal{V}_{\alpha}). \end{align*}$$
In addition, we calculate
$$\begin{align*}\mathrm{Hom}_{H_n(0)}(\mathcal{V}_{\alpha}, \mathcal{V}_{\beta}) \quad \text{and} \quad \mathrm{Ext}_{H_n(0)}^1(\mathcal{V}_{\alpha}, \mathcal{V}_{\beta}) \end{align*}$$
for all
$\beta \le _l \alpha $
, where
$\le _l$
represents the lexicographic order on compositions. In the following, let us explain our results in more detail.
Let
$\alpha = (\alpha _1,\alpha _2,\ldots , \alpha _{\ell (\alpha )})$
be a composition of n. The first main result concerns a minimal projective presentation of
$\mathcal {V}_{\alpha }$
. The projective cover
$\Phi : \mathbf {P}_{\alpha } \rightarrow \mathcal {V}_{\alpha }$
, of
$\mathcal {V}_{\alpha }$
has already been provided in [Reference Choi, Kim, Nam and Oh12, Theorem 3.2]. Let
$\mathcal {I}(\alpha ) := \{1 \le i \le \ell (\alpha )-1 \mid \alpha _{i+1} \neq 1 \}$
, and for each
$i \in \mathcal {I}(\alpha )$
, let
${\boldsymbol {\unicode{x3b1} }}^{(i)}$
be the generalised composition
$$\begin{align*}(\alpha_1, \alpha_2, \ldots, \alpha_{i-1}, \alpha_i +1, \alpha_{i+1} - 1) \oplus (\alpha_{i+2} , \alpha_{i+3}, \ldots, \alpha_{\ell(\alpha)}). \end{align*}$$
Then we construct a
$\mathbb C$
-linear map
which turns out to be an
$H_n(0)$
-module homomorphism. Additionally, we show that
$$\begin{align*}\ker (\Phi) = \mathrm{Im}(\partial_1) \quad \text{and} \quad \ker(\partial_1) \subseteq \mathrm{rad} \left(\bigoplus_{i \in \mathcal{I}(\alpha)} \mathbf{P}_{{\boldsymbol{\unicode{x3b1}}}^{(i)}} \right). \end{align*}$$
Hence we obtain the following minimal projective presentation of
$\mathcal {V}_{\alpha }$
which enables us to derive that
$$\begin{align*}\mathrm{Ext}_{H_n(0)}^1(\mathcal{V}_{\alpha},\mathbf{F}_{\beta}) \cong \begin{cases} \mathbb C & \text{if } \beta \in \mathcal{J}(\alpha),\\ 0 & \text{otherwise} \end{cases} \end{align*}$$
with
$\mathcal {J}(\alpha ) := \bigcup _{i \in \mathcal {I}(\alpha )} [{\boldsymbol {\unicode{x3b1} }}^{(i)}]$
. Here, given a generalised composition
${\boldsymbol {\unicode{x3b1} }} = \alpha ^{(1)} \oplus \alpha ^{(2)} \oplus \cdots \oplus \alpha ^{(p)}$
, we are using the notation
$[{\boldsymbol {\unicode{x3b1} }}]$
to denote the set of all compositions of the form
$$ \begin{align*} \alpha^{(1)} \ \square \ \alpha^{(2)} \ \square \ \cdots \ \square \ \alpha^{(p)}, \end{align*} $$
where
$\square $
is the concatenation
$\cdot $
or near concatenation
$\odot $
(Theorem 3.3).
The second main result concerns a minimal injective presentation of
$\mathcal {V}_{\alpha }$
. Since
$H_n(0)$
is a Frobenius algebra, every finitely generated injective
$H_n(0)$
-module is projective. But unlike the projective cover of
$\mathcal {V}_{\alpha }$
, there are no known results for an injective hull of
$\mathcal {V}_{\alpha }$
. We consider the generalised composition
$$ \begin{align*} \underline{{\boldsymbol{\unicode{x3b1}}}} := (\alpha_{k_1} -1) \oplus (\alpha_{k_2}-1) \oplus \cdots \oplus (\alpha_{k_{m-1}}-1) \oplus (\alpha_{k_m},1^{\ell(\alpha)-1}), \end{align*} $$
where
$$\begin{align*}\{k_1 < k_2 < \cdots < k_m\}=\{ 1\le i \le \ell(\alpha) : \alpha_{i}> 1\}. \end{align*}$$
Then we construct an injective
$H_n(0)$
-module homomorphism
$\epsilon : \mathcal {V}_{\alpha } \rightarrow \mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}}$
and prove that it is an injective hull of
$\mathcal {V}_{\alpha }$
, equivalently,
$\mathrm {soc}(\mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}}) \subseteq \epsilon (\mathcal {V}_{\alpha })$
(Theorem 4.1). The next step is to find a map
$\partial ^1: \mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}} \to \boldsymbol {I}$
with
$\boldsymbol {I}$
injective such that
is a minimal injective presentation. To do this, to each index
$1 \leq j \leq m$
, we assign the generalised composition
$$ \begin{align*}\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}: = \begin{cases} (\alpha_{k_1}-1) \oplus \cdots \oplus (\alpha_{k_j} - 2) \oplus \cdots \oplus (\alpha_{k_m}, 1^{\ell(\alpha)-k_j+1}) \oplus (1^{k_j-1}) & \text{ if } 1 \leq j < m, \\ (\alpha_{k_1}-1 ) \oplus \cdots \oplus (\alpha_{k_{m-1}}-1) \oplus \left((\alpha_{k_m}-1,1^{\ell(\alpha)-k_j+1}) \cdot (1^{k_j-1})\right) & \text{ if } j = m. \end{cases} \end{align*} $$
Then we construct a
$\mathbb C$
-linear map
which turns out to be an
$H_n(0)$
-module homomorphism. We also show that
$$\begin{align*}\mathrm{Im}(\epsilon) = \ker(\partial^1) \quad \text{ and } \quad \mathrm{soc}\left( \boldsymbol{I} \right) \subseteq \mathrm{Im}(\partial^1). \end{align*}$$
Hence we have the following minimal injective presentation of
$\mathcal {V}_{\alpha }$
:
Let
$\Omega ^{-1}(\mathcal {V}_{\alpha })$
be the cosyzygy module of
$\mathcal {V}_{\alpha }$
, the cokernel of
$\epsilon $
. Applying the formula
$\mathrm {Ext}_{H_n(0)}^1(\mathbf {F}_{\beta },\mathcal {V}_{\alpha }) \cong \mathrm {Hom}_{H_n(0)}(\mathbf {F}_{\beta }, \Omega ^{-1}(\mathcal {V}_{\alpha }))$
to this minimal injective presentation enables us to derive that
$$\begin{align*}\mathrm{Ext}_{H_n(0)}^1(\mathbf{F}_{\beta},\mathcal{V}_{\alpha}) \cong \begin{cases} \mathbb C^{[\mathcal{L}(\alpha):\beta^{\mathrm{r}}]} & \text{if } \beta^{\mathrm{r}} \in \mathcal{L}(\alpha),\\ 0 & \text{otherwise,} \end{cases} \end{align*}$$
where
$\mathcal {L}(\alpha )$
is the multiset
$\bigcup _{1 \leq j \leq m} [\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}]$
,
$\beta ^{\mathrm {r}}$
the reverse composition of
$\beta $
and
$[\mathcal {L}(\alpha ):\beta ^{\mathrm {r}}]$
the multiplicity of
$\beta ^{\mathrm {r}}$
in
$\mathcal {L}(\alpha )$
(Theorem 4.3).
The third main result concerns
$\mathrm {Ext}^i_{H_n(0)}(\mathcal {V}_{\alpha }, \mathcal {V}_{\beta })$
for
$i=0,1$
. We show that whenever
$\beta \le _l \alpha $
,
$$ \begin{align*} \mathrm{Ext}_{H_n(0)}^1(\mathcal{V}_{\alpha},\mathcal{V}_{\beta}) = 0 \qquad \text{and} \qquad \mathrm{Ext}_{H_n(0)}^0(\mathcal{V}_{\alpha}, \mathcal{V}_{\beta}) \cong\begin{cases} \mathbb C & \text{if } \beta = \alpha, \\ 0 & \text{otherwise}. \end{cases} \end{align*} $$
Given a finite-dimensional
$H_n(0)$
-module M, we say that M is rigid if
$\mathrm {Ext}_{H_n(0)}^1(M,M)=0$
and essentially rigid if
$\mathrm {Hom}_{H_n(0)}(\Omega (M),M)=0$
, where
$\Omega (M)$
is the syzygy module of M. With this definition, we also prove that
$\mathcal {V}_{\alpha }$
is essentially rigid for every composition
$\alpha $
of n (Theorem 5.4). In the case where
$\beta>_l \alpha $
, the structure of
$\mathrm {Ext}^i_{H_n(0)}(\mathcal {V}_{\alpha }, \mathcal {V}_{\beta })$
for
$i=0,1$
is still beyond our understanding. For instance, each map in
$\mathrm {Ext}^0_{H_n(0)}(\mathcal {V}_{\alpha }, \mathcal {V}_{\beta })$
is completely determined by the value of a cyclic generator of
$\mathcal {V}_{\alpha }$
. However, at the moment, it seems difficult to characterise all possible values the generator can have. Instead, we view
$\mathrm {Ext}^0_{H_n(0)}(\mathcal {V}_{\alpha }, \mathcal {V}_{\beta })$
as the set of
$H_n(0)$
-module homomorphisms from
$\mathbf {P}_{\alpha }$
to
$\mathcal {V}_{\beta }$
that vanish on
$\Omega (\mathcal {V}_{\alpha })$
. The most important reason for taking this view is that we know a minimal generating set of
$\mathcal {V}_{\alpha }$
as well as a combinatorial description of
$\dim _{\mathbb C}\mathrm {Ext}^0_{H_n(0)}(\mathbf {P}_{\alpha }, \mathcal {V}_{\beta })$
. An approach in this direction is given in Theorem 5.6.
This paper is organised as follows. In Section 2, we introduce the prerequisites on the
$0$
-Hecke algebra, including the quasisymmetric characteristic, standard ribbon tableaux, standard immaculate tableaux and
$H_n(0)$
-modules associated to such tableaux. In Section 3, we provide a minimal projective presentation of
$\mathcal {V}_{\alpha }$
and
$\mathrm {Ext}^1_{H_n(0)}(\mathcal {V}_{\alpha }, \mathbf {F}_{\beta })$
. And in Section 4, we provide a minimal injective presentation of
$\mathcal {V}_{\alpha }$
and
$\mathrm {Ext}^1_{H_n(0)}(\mathbf {F}_{\beta },\mathcal {V}_{\alpha })$
. In Section 5, we investigate
$\mathrm {Ext}^i_{H_n(0)}(\mathcal {V}_{\alpha }, \mathcal {V}_{\beta })$
for
$i=0,1$
. Section 6 is devoted to proving the first and second main results of this paper. In the last section, we provide some future directions to pursue.
2 Preliminaries
In this section, n denotes a nonnegative integer. Define
$[n]$
to be
$\{1,2,\ldots , n\}$
if
$n> 0$
or
$\emptyset $
otherwise. In addition, we set
$[-1]:=\emptyset $
. For positive integers
$i\le j$
, set
$[i,j]:=\{i,i+1,\ldots , j\}$
.
2.1 Compositions and their diagrams
A composition
$\alpha $
of a nonnegative integer n, denoted by
$\alpha \models n$
, is a finite ordered list of positive integers
$(\alpha _1, \alpha _2, \ldots , \alpha _k)$
satisfying
$\sum _{i=1}^k \alpha _i = n$
. For each
$1 \le i \le k$
, let us call
$\alpha _i$
a part of
$\alpha $
. And we call
$k =: \ell (\alpha )$
the length of
$\alpha $
and
$n =:|\alpha |$
the size of
$\alpha $
. For convenience, we define the empty composition
$\emptyset $
to be the unique composition of size and length
$0$
. A generalised composition
${\boldsymbol {\unicode{x3b1} }}$
of n is a formal sum
$\alpha ^{(1)} \oplus \alpha ^{(2)} \oplus \cdots \oplus \alpha ^{(k)}$
, where
$\alpha ^{(i)} \models n_i$
for positive integers
$n_i$
s with
$n_1 + n_2 + \cdots + n_k = n$
.
For
$\alpha = (\alpha _1, \alpha _2, \ldots , \alpha _{\ell (\alpha )}) \models n$
, we define the composition diagram
$\mathtt {cd}(\alpha )$
of
$\alpha $
as a left-justified array of n boxes where the ith row from the top has
$\alpha _i$
boxes for
$1 \le i \le k$
. We also define the ribbon diagram
$\mathtt {rd}(\alpha )$
of
$\alpha $
by the connected skew diagram without
$2 \times 2$
boxes, such that the ith column from the left has
$\alpha _i$
boxes. Then for a generalised composition
${\boldsymbol {\unicode{x3b1} }}$
of n, we define the generalised ribbon diagram
$\mathtt {rd}({\boldsymbol {\unicode{x3b1} }})$
of
${\boldsymbol {\unicode{x3b1} }}$
to be the skew diagram whose connected components are
$\mathtt {rd}(\alpha ^{(1)}), \mathtt {rd}(\alpha ^{(2)}), \ldots , \mathtt {rd}(\alpha ^{(k)})$
such that
$\mathtt {rd}(\alpha ^{(i+1)})$
is strictly to the northeast of
$\mathtt {rd}(\alpha ^{(i)})$
for
$i = 1, 2, \ldots , k-1$
. For example, if
$\alpha = (3,1,2)$
and
${\boldsymbol {\unicode{x3b1} }} = (2,1) \oplus (1,1)$
, then
Given
$\alpha = (\alpha _1, \alpha _2, \ldots ,\alpha _{\ell (\alpha )}) \models n$
and
$I = \{i_1 < i_2 < \cdots < i_k\} \subset [n-1]$
, let
$$ \begin{align*} &\mathrm{set}(\alpha) := \{\alpha_1,\alpha_1+\alpha_2,\ldots, \alpha_1 + \alpha_2 + \cdots + \alpha_{\ell(\alpha)-1}\}, \\ &\mathrm{comp}(I) := (i_1,i_2 - i_1,\ldots,n-i_k). \end{align*} $$
The set of compositions of n is in bijection with the set of subsets of
$[n-1]$
under the correspondence
$\alpha \mapsto \mathrm {set}(\alpha )$
(or
$I \mapsto \mathrm {comp}(I)$
). Let
$\alpha ^{\mathrm {r}}$
denote the composition
$(\alpha _{\ell (\alpha )}, \alpha _{\ell (\alpha )-1}, \ldots , \alpha _1)$
.
For compositions
$\alpha = (\alpha _{1}, \alpha _{2}, \ldots , \alpha _{k})$
and
$\beta = (\beta _{1}, \beta _{2}, \ldots , \beta _{l})$
, let
$\alpha \cdot \beta $
be the concatenation and
$\alpha \odot \beta $
the near concatenation of
$\alpha $
and
$\beta $
. In other words,
$ \alpha \cdot \beta = (\alpha _1, \alpha _2, \ldots , \alpha _k, \beta _1, \beta _2, \ldots , \beta _l)$
and
$\alpha \odot \beta = (\alpha _1,\ldots , \alpha _{k-1},\alpha _k + \beta _1,\beta _2, \ldots , \beta _l)$
. For a generalised composition
${\boldsymbol {\unicode{x3b1} }} = \alpha ^{(1)} \oplus \alpha ^{(2)} \oplus \cdots \oplus \alpha ^{(m)}$
, define
$$ \begin{align*} [{\boldsymbol{\unicode{x3b1}}}] := \{\alpha^{(1)} \ \square \ \alpha^{(2)} \ \square \ \cdots \ \square \ \alpha^{(m)} \mid \square = \cdot \text{ or } \odot\}. \end{align*} $$
2.2 The
$0$
-Hecke algebra and the quasisymmetric characteristic
The symmetric group
$\Sigma _n$
is generated by simple transpositions
$s_i := (i \ i \hspace {-.5ex} + \hspace {-.5ex} 1)$
with
$1 \le i \le n-1$
. An expression for
$\sigma \in \Sigma _n$
of the form
$s_{i_1} s_{i_2} \cdots s_{i_p}$
that uses the minimal number of simple transpositions is called a reduced expression for
$\sigma $
. The number of simple transpositions in any reduced expression for
$\sigma $
, denoted by
$\ell (\sigma )$
, is called the length of
$\sigma $
.
The
$0$
-Hecke algebra
$H_n(0)$
is the
$\mathbb C$
-algebra generated by
$\pi _1, \pi _2, \ldots ,\pi _{n-1}$
subject to the following relations:
$$ \begin{align*} \pi_i^2 &= \pi_i \quad \text{for } 1\le i \le n-1,\\ \pi_i \pi_{i+1} \pi_i &= \pi_{i+1} \pi_i \pi_{i+1} \quad \text{for } 1\le i \le n-2,\\ \pi_i \pi_j &=\pi_j \pi_i \quad \text{if } |i-j| \ge 2. \end{align*} $$
Pick up any reduced expression
$s_{i_1} s_{i_2} \cdots s_{i_p}$
for a permutation
$\sigma \in \Sigma _n$
. It is well known that the element
$\pi _{\sigma } := \pi _{i_1} \pi _{i_2} \cdots \pi _{i_p}$
is independent of the choice of reduced expressions and
$\{\pi _{\sigma } \mid \sigma \in \Sigma _n\}$
is a basis for
$H_n(0)$
. For later use, set
$$ \begin{align*} \pi_{[i, j]} := \pi_{i} \pi_{i+1} \cdots \pi_{j} \quad \text{and} \quad \pi_{[i, j]^{\mathrm{r}}} := \pi_{j} \pi_{j-1} \cdots \pi_{i} \end{align*} $$
for all
$1 \le i \le j \le n-1$
.
Let
$\mathcal {R}(H_n(0))$
denote the
$\mathbb Z$
-span of (representatives of) the isomorphism classes of finite-dimensional representations of
$H_n(0)$
. The isomorphism class corresponding to an
$H_n(0)$
-module M will be denoted by
$[M]$
. The Grothendieck group
$\mathcal {G}_0(H_n(0))$
is the quotient of
$\mathcal {R}(H_n(0))$
modulo the relations
$[M] = [M'] + [M"]$
whenever there exists a short exact sequence
$0 \rightarrow M' \rightarrow M \rightarrow M" \rightarrow 0$
. The equivalence classes of irreducible representations of
$H_n(0)$
form a free
$\mathbb Z$
-basis for
$\mathcal {G}_0(H_n(0))$
. Let
$$\begin{align*}\mathcal{G} := \bigoplus_{n \ge 0} \mathcal{G}_0(H_n(0)). \end{align*}$$
According to [Reference Norton25], there are
$2^{n-1}$
distinct irreducible representations of
$H_n(0)$
. They are naturally indexed by compositions of n. Let
$\mathbf {F}_{\alpha }$
denote the
$1$
-dimensional
$\mathbb C$
-vector space corresponding to
$\alpha \models n$
, spanned by a vector
$v_{\alpha }$
. For each
$1\le i \le n-1$
, define an action of the generator
$\pi _i$
of
$H_n(0)$
as follows:
$$\begin{align*}\pi_i \cdot v_{\alpha} = \begin{cases} 0 & i \in \mathrm{set}(\alpha),\\ v_{\alpha} & i \notin \mathrm{set}(\alpha). \end{cases} \end{align*}$$
Then
$\mathbf {F}_{\alpha }$
is an irreducible
$1$
-dimensional
$H_n(0)$
-representation.
In the following, let us review the connection between
$\mathcal {G}$
and the ring
$\mathrm {QSym}$
of quasisymmetric functions. Quasisymmetric functions are power series of bounded degree in variables
$x_{1},x_{2},x_{3},\ldots $
with coefficients in
$\mathbb Z$
that are shift invariant in the sense that the coefficient of the monomial
$x_{1}^{\alpha _{1}}x_{2}^{\alpha _{2}}\cdots x_{k}^{\alpha _{k}}$
is equal to the coefficient of the monomial
$x_{i_{1}}^{\alpha _{1}}x_{i_{2}}^{\alpha _{2}}\cdots x_{i_{k}}^{\alpha _{k}}$
for any strictly increasing sequence of positive integers
$i_{1}<i_{2}<\cdots <i_{k}$
indexing the variables and any positive integer sequence
$(\alpha _{1},\alpha _{2},\ldots ,\alpha _{k})$
of exponents.
Given a composition
$\alpha $
, the fundamental quasisymmetric function
$F_{\alpha }$
is defined by
$F_{\emptyset } = 1$
and
$$\begin{align*}F_{\alpha} = \sum_{\substack{1 \le i_1 \le i_2 \le \cdots \le i_k \\ i_j < i_{j+1} \text{ if } j \in \mathrm{set}(\alpha)}} x_{i_1} x_{i_2} \cdots x_{i_k}. \end{align*}$$
It is well known that
$\{F_{\alpha } \mid \alpha \text { is a composition}\}$
is a basis for
$\mathrm {QSym}$
. In [Reference Duchamp, Krob, Leclerc and Thibon15], Duchamp, Krob, Leclerc and Thibon show that, when
$\mathcal {G}$
is equipped with induction product, the linear map
$$ \begin{align*} \mathrm{ch} : \mathcal{G} \rightarrow \mathrm{QSym}, \quad [\mathbf{F}_{\alpha}] \mapsto F_{\alpha}, \end{align*} $$
called the quasisymmetric characteristic, is a ring isomorphism.
2.3 Projective modules of the
$0$
-Hecke algebra
We begin this subsection by recalling that
$H_n(0)$
is a Frobenius algebra. Hence it is self-injective, so that finitely generated projective and injective modules coincide (see [Reference Duchamp, Hivert and Thibon14, Proposition 4.1], [Reference Fayers16, Proposition 4.1] and [Reference Benson3, Proposition 1.6.2]).
It was Norton [Reference Norton25] who first classified all projective indecomposable modules of
$H_n(0)$
up to isomorphism that bijectively correspond to compositions of n. Later, Huang [Reference Huang20] provided a combinatorial description of these modules and their induction products as well by using standard ribbon tableaux of generalised composition shape. We review Huang’s description very briefly here.
Definition 2.1. For a generalised composition
${\boldsymbol {\unicode{x3b1} }}$
of n, a standard ribbon tableau (SRT) of shape
${\boldsymbol {\unicode{x3b1} }}$
is a filling of
$\mathtt {rd}({\boldsymbol {\unicode{x3b1} }})$
with
$\{1,2,\ldots ,n\}$
such that the entries are all distinct, the entries in each row are increasing from left to right, and the entries in each column are increasing from top to bottom.
Let
$\mathrm {SRT}({\boldsymbol {\unicode{x3b1} }})$
denote the set of all
$\mathrm {SRT}$
x of shape
${\boldsymbol {\unicode{x3b1} }}$
. For
$T \in \mathrm {SRT}({\boldsymbol {\unicode{x3b1} }})$
, let
$$ \begin{align*} \mathrm{Des}(T) := \{i \in [n-1] \mid i \text{ appears weakly below } i+1 \text{ in } T \}. \end{align*} $$
Define an
$H_n(0)$
-action on the
$\mathbb C$
-span of
$\mathrm {SRT}({\boldsymbol {\unicode{x3b1} }})$
by
$$ \begin{align} \pi_i \cdot T = \begin{cases} T & \text{if } i \notin \mathrm{Des}(T),\\ 0 & \text{if } i \text{ and } i+1 \text{ are in the same row of } T,\\ s_i \cdot T & \text{if } i \text{ appears strictly below } i+1 \text{ in } T \end{cases} \end{align} $$
for
$1\le i \le n-1$
and
$T \in \mathrm {SRT}({\boldsymbol {\unicode{x3b1} }})$
. Here
$s_i \cdot T$
is obtained from T by swapping i and
$i+1$
. The resulting module is denoted by
$\mathbf {P}_{\boldsymbol {\unicode{x3b1} }}$
. It is known that the set
$\{\mathbf {P}_{\alpha } \mid \alpha \models n\}$
forms a complete family of non-isomorphic projective indecomposable
$H_n(0)$
-modules and
$\mathbf {P}_{\alpha } /\mathrm {rad}(\mathbf {P}_{\alpha }) \cong \mathbf {F}_{\alpha }$
, where
$\mathrm {rad}(\mathbf {P}_{\alpha })$
is the radical of
$\mathbf {P}_{\alpha }$
(for details; see [Reference Huang20, Reference Norton25]).
Remark 2.2. It should be pointed out that the ribbon diagram and
$H_n(0)$
-action used here are slightly different from those in Huang’s work [Reference Huang20]. He describes the
$H_n(0)$
-action on
$\mathbf {P}_{\boldsymbol {\unicode{x3b1} }}$
in terms of
$\overline {\pi }_i$
s, where
$\overline {\pi }_i= \pi _i -1$
. On the other hand, we use
$\pi _i$
s because the
$H_n(0)$
-action on
$\mathcal {V}_{\alpha }$
is described in terms of
$\pi _i$
s. This leads us to adjust Huang’s ribbon diagram to the form of
$\mathtt {rd}({\boldsymbol {\unicode{x3b1} }})$
.
Given any generalised composition
${\boldsymbol {\unicode{x3b1} }}$
, let
$T_{\boldsymbol {\unicode{x3b1} }} \in \mathrm {SRT}({\boldsymbol {\unicode{x3b1} }})$
be the
$\mathrm {SRT}$
obtained by filling
$\mathtt {rd}({\boldsymbol {\unicode{x3b1} }})$
with entries
$1, 2, \ldots , n$
from top to bottom and from left to right. Since
$\mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}}$
is cyclically generated by
$T_{\boldsymbol {\unicode{x3b1} }}$
, we call
$T_{\boldsymbol {\unicode{x3b1} }}$
the source tableau of
$\mathbf {P}_{\boldsymbol {\unicode{x3b1} }}$
. For any
$\mathrm {SRT} T$
, let
$\mathbf {w}(T)$
be the word obtained by reading the entries from left to right, starting with the bottom row. Using this reading, Huang [Reference Huang20] shows the following result.
Theorem 2.3 ([Reference Huang20, Theorem 3.3]).
Let
${\boldsymbol {\unicode{x3b1} }}$
be a generalised composition of n. Then
$\mathbf {P}_{\boldsymbol {\unicode{x3b1} }}$
is isomorphic to
$\bigoplus _{\beta \in [{\boldsymbol {\unicode{x3b1} }}]} \mathbf {P}_{\beta }$
as an
$H_n(0)$
-module.
For later use, for every generalised composition
${\boldsymbol {\unicode{x3b1} }}$
of n, we define a partial order
$\le $
on
$\mathrm {SRT}({\boldsymbol {\unicode{x3b1} }})$
by
$$ \begin{align*} T \le T' \quad \text{if and only if} \quad T' = \pi_{\sigma} \cdot T \quad \text{for some } \sigma \in \Sigma_n. \end{align*} $$
As usual, whenever
$T \le T'$
, the notation
$[T, T']$
denotes the interval
$\{U \in \mathrm {SRT}({\boldsymbol {\unicode{x3b1} }}) \mid T \le U \le T'\}$
.
2.4 The
$H_n(0)$
-action on standard immaculate tableaux
Noncommutative Bernstein operators were introduced by Berg, Bergeron, Saliola, Serrano and Zabrocki [Reference Berg, Bergeron, Saliola, Serrano and Zabrocki4]. Applied to the identity of the ring
$\mathrm {NSym}$
of noncommutative symmetric functions, they yield the immaculate functions, which form a basis of
$\mathrm {NSym}$
. Soon after, using the combinatorial objects called standard immaculate tableaux, they constructed indecomposable
$H_n(0)$
-modules whose quasisymmetric characteristics are the quasisymmetric functions that are dual to immaculate functions (see [Reference Berg, Bergeron, Saliola, Serrano and Zabrocki5]).
Definition 2.4. Let
$\alpha \models n$
. A standard immaculate tableau (SIT) of shape
$\alpha $
is a filling
$\mathscr {T}$
of the composition diagram
$\mathtt {cd}(\alpha )$
with
$\{1,2,\ldots ,n\}$
such that the entries are all distinct, the entries in each row increase from left to right, and the entries in the first column increase from top to bottom.
We denote the set of all SITx of shape
$\alpha $
by
$\mathrm {SIT}(\alpha )$
. For
$\mathscr {T} \in \mathrm {SIT}(\alpha )$
, let
$$ \begin{align*} \mathrm{Des}(\mathscr{T}) := \{i \in [n-1] \mid i \text{ appears strictly above } i+1 \text{ in } \mathscr{T} \}. \end{align*} $$
Define an
$H_n(0)$
-action on
$\mathbb C$
-span of
$\mathrm {SIT}(\alpha )$
by
$$ \begin{align} \pi_i \cdot \mathscr{T} = \begin{cases} \mathscr{T} & \text{if } i \notin \mathrm{Des}(\mathscr{T}),\\ 0 & \text{if } i \text{ and } i+1 \text{ are in the first column of } \mathscr{T},\\ s_i \cdot \mathscr{T} & \text{otherwise} \end{cases} \end{align} $$
for
$1\le i \le n-1$
and
$\mathscr {T} \in \mathrm {SIT}(\alpha )$
. Here
$s_i \cdot \mathscr {T}$
is obtained from
$\mathscr {T}$
by swapping i and
$i+1$
. The resulting module is denoted by
$\mathcal {V}_{\alpha }$
.
Let
$\mathscr {T}_{\alpha } \in \mathrm {SIT}(\alpha )$
be the SIT obtained by filling
$\mathtt {cd}(\alpha )$
with entries
$1, 2, \ldots , n$
from left to right and from top to bottom.
Theorem 2.5 ([Reference Berg, Bergeron, Saliola, Serrano and Zabrocki5]).
For
$\alpha \models n$
,
$\mathcal {V}_{\alpha }$
is a cyclic indecomposable
$H_n(0)$
-module generated by
$\mathscr {T}_{\alpha }$
whose quasisymmetric characteristic is the dual immaculate quasisymmetric function
$\mathfrak {S}^*_{\alpha }$
.
Convention. Regardless of a ribbon diagram or composition diagram, columns are numbered from left to right. To avoid possible confusion, we adopt the following notation:
-
(i) Let T be a filling of the ribbon diagram
$\mathtt {rd}({\boldsymbol {\unicode{x3b1} }})$
.-
-
$T^i_j$
= the entry at the ith box from the top of the jth column -
-
$T_j^{-1}$
= the entry at the bottom-most box in the jth column -
-
$T^{\bullet }_j$
= the set of all entries in the jth column
-
-
(ii) Let
$\mathscr {T}$
be a filling of the composition diagram
$\mathtt {cd}(\alpha )$
.-
-
$\mathscr {T}_{i,j}$
= the entry at the box in the ith row (from the top) and in the jth column
-
3 A minimal projective presentation of
$\mathcal {V}_{\alpha }$
and
$\mathrm {Ext}^1_{H_n(0)}(\mathcal {V}_{\alpha }, \mathbf {F}_{\beta })$
From now on,
$\alpha $
denotes an arbitrarily chosen composition of n. We here construct a minimal projective presentation of
$\mathcal {V}_{\alpha }$
. Using this, we compute
$\mathrm {Ext}^1_{H_n(0)}(\mathcal {V}_{\alpha }, \mathbf {F}_{\beta })$
for each
$\beta \models n$
.
Firstly, let us introduce necessary terminologies and notation. Let
$A,B$
be finitely generated
$H_n(0)$
-modules. A surjective
$H_n(0)$
-module homomorphism
$f:A\to B$
is called an essential epimorphism if an
$H_n(0)$
-module homomorphism
$g: X\to A$
is surjective whenever
$f \circ g:X\to B$
is surjective. A projective cover of A is an essential epimorphism
$f:P\to A$
with P projective that always exists and is unique up to isomorphism. It is well known that
$f:P\to A$
is an essential epimorphism if and only if
$\ker (f) \subset \mathrm {rad}(P)$
(for instance, see [Reference Auslander, Reiten and Smalø1, Proposition I.3.6]). For simplicity, when f is clear in the context, we just write
$\Omega (A)$
for
$\ker (f)$
and call it the syzygy module of A. An exact sequence
with projective modules
$P_0$
and
$P_1$
is called a minimal projective presentation if the
$H_n(0)$
-module homomorphisms
$\epsilon : P_0 \rightarrow A$
and
$\partial _1: P_1 \rightarrow \Omega (A)$
are projective covers of A and
$\Omega (A)$
, respectively.
Next, let us review the projective cover of
$\mathcal {V}_{\alpha }$
obtained in [Reference Choi, Kim, Nam and Oh12]. Given any
$T \in \mathrm {SRT}(\alpha )$
, let
$\mathscr {T}_T$
be the filling of
$\mathtt {cd}(\alpha )$
given by
$(\mathscr {T}_T)_{i,j} = T^{j}_{i}$
. Then we define a
$\mathbb C$
-linear map
$\Phi : \mathbf {P}_{\alpha } \rightarrow \mathcal {V}_{\alpha }$
by
$$ \begin{align} \Phi(T) = \begin{cases} \mathscr{T}_T & \text{if } \mathscr{T}_T \text{ is an SIT,}\\ 0 & \text{otherwise.} \end{cases} \end{align} $$
For example, if
$\alpha = (1,2,2)$
and
then
Therefore,
$\Phi (T_1) = \mathscr {T}_{T_1}$
and
$\Phi (T_2) = 0$
.
Theorem 3.1 ([Reference Choi, Kim, Nam and Oh12, Theorem 3.2]).
For
$\alpha \models n$
,
$\Phi : \mathbf {P}_{\alpha } \rightarrow \mathcal {V}_{\alpha }$
is a projective cover of
$\mathcal {V}_{\alpha }$
.
Now, let us construct a projective cover of
$\Omega (\mathcal {V}_{\alpha })$
for each
$\alpha \models n$
. To do this, we provide necessary notation. For each integer
$0\le i \le \ell (\alpha )-1$
, we set
$m_i$
to be
$\sum _{j = 1}^{i}\alpha _j$
for
$i> 0$
and
$m_0 = 0$
. Let
$$\begin{align*}\mathcal{I}(\alpha) := \{1 \le i \le \ell(\alpha)-1 \mid \alpha_{i+1} \neq 1 \}. \end{align*}$$
Given
$i \in \mathcal {I}(\alpha )$
, let
$$\begin{align*}T^{(i)}_{\alpha} := \pi_{[m_{i-1} + 1, m_{i}]} \cdot T_{\alpha} \end{align*}$$
and
$$\begin{align*}{\boldsymbol{\unicode{x3b1}}}^{(i)} := (\alpha_1, \alpha_2, \ldots, \alpha_{i-1}, \alpha_i +1, \alpha_{i+1} - 1) \oplus (\alpha_{i+2} , \alpha_{i+3}, \ldots, \alpha_{\ell(\alpha)}). \end{align*}$$
Given an SRT
$\tau $
of shape
${\boldsymbol {\unicode{x3b1} }}^{(i)} (i \in \mathcal {I}(\alpha ))$
, define
$L(\tau )$
to be the filling of
$\mathtt {rd}(\alpha )$
whose entries in each column are increasing from top to bottom and whose columns are given as follows: for
$1 \le p \le \ell (\alpha )$
,
$$ \begin{align} L(\tau)_p^{\bullet} = \begin{cases} \tau_i^{\bullet} \setminus \{\tau_i^1\} & \text{if } p = i,\\ \tau_{i+1}^{\bullet} \cup \{\tau_i^1\} & \text{if } p = i+1,\\ \tau_p^{\bullet} & \text{otherwise.}\\ \end{cases} \end{align} $$
Example 3.2. For
we have
For each
$i \in \mathcal {I}(\alpha )$
, we define a
$\mathbb C$
-linear map
$ \partial _1^{(i)}: \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}} \rightarrow H_n(0) \cdot T^{(i)}_{\alpha }$
by
$$\begin{align*}\partial_1^{(i)} (\tau) = \begin{cases} L(\tau) & \text{if } L(\tau) \in \mathrm{SRT}(\alpha),\\ 0 & \text{otherwise.} \end{cases} \end{align*}$$
Then we define a
$\mathbb C$
-linear map
$\partial _1 : \bigoplus _{i \in \mathcal {I}(\alpha )} \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}} \rightarrow \mathbf {P}_{\alpha }$
by
$$ \begin{align*}\partial_1 := \sum_{i \in \mathcal{I}(\alpha)} \partial_1^{(i)}. \end{align*} $$
Theorem 3.3 (This will be proven in Subsection 6.1).
Let
$\alpha $
be a composition of n.
-
(a)
$\mathrm {Im}(\partial _1) = \Omega (\mathcal {V}_{\alpha })$
and
$\partial _1 : \bigoplus _{i \in \mathcal {I}(\alpha )} \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}} \rightarrow \Omega (\mathcal {V}_{\alpha })$
is a projective cover of
$\Omega (\mathcal {V}_{\alpha })$
. -
(b) Let
$\mathcal {J}(\alpha ) := \bigcup _{i \in \mathcal {I}(\alpha )} [{\boldsymbol {\unicode{x3b1} }}^{(i)}]$
. Then we have
$$\begin{align*}\mathrm{Ext}_{H_n(0)}^1(\mathcal{V}_{\alpha},\mathbf{F}_{\beta}) \cong \begin{cases} \mathbb C & \text{if } \beta \in \mathcal{J}(\alpha), \\ 0 & \text{otherwise.} \end{cases} \end{align*}$$
Example 3.4. Let
$\alpha = (1,2,1)$
. Then we have that
$\mathcal {I}(\alpha ) = \{1\}$
and
${\boldsymbol {\unicode{x3b1} }}^{(1)} = (2,1) \oplus (1)$
.
(a) The map
$\partial _1: \mathbf {P}_{(2,1) \oplus (1)} \rightarrow \mathbf {P}_{(1,2,1)}$
is illustrated in Figure 1, where the entries i in red in each SRT
$T$
are used to indicate that
$\pi _i \cdot T = 0$
.
Figure 1
$\partial _1: \mathbf {P}_{(2,1) \oplus (1)} \rightarrow \mathbf {P}_{(1,2,1)}$
.
(b) Note that
$\mathcal {J}(\alpha ) = [{\boldsymbol {\unicode{x3b1} }}^{(1)}] = \{(2,2),(2,1,1)\}$
. By Theorem 3.3(b), we have
$$\begin{align*}\dim \mathrm{Ext}_{H_n(0)}^1(\mathcal{V}_{(1,2,1)},\mathbf{F}_{\beta}) = \begin{cases} 1 & \text{ if } \beta = (2,2) \text{ or } (2,1,1), \\ 0 & \text{ otherwise.} \end{cases} \end{align*}$$
4 A minimal injective presentation of
$\mathcal {V}_{\alpha }$
and
$\mathrm {Ext}^1_{H_n(0)}(\mathbf {F}_{\beta },\mathcal {V}_{\alpha })$
As before,
$\alpha $
denotes an arbitrarily chosen composition of n. In this section, we construct a minimal injective presentation of
$\mathcal {V}_{\alpha }$
. Using this, we compute
$\mathrm {Ext}^1_{H_n(0)}(\mathbf {F}_{\beta },\mathcal {V}_{\alpha })$
for each
$\beta \models n$
.
Let us introduce necessary terminologies and notation. Let
$M,N$
be finitely generated
$H_n(0)$
-modules with
$N \subsetneq M$
. We say that M is an essential extension of N if
$X\cap N \ne 0$
for all nonzero submodules X of M. An injective
$H_n(0)$
-module homomorphism
$\iota : M \rightarrow \boldsymbol {I}$
with
$\boldsymbol {I}$
injective is called an injective hull of M if
$\boldsymbol {I}$
is an essential extension of
$\iota (M)$
that always exists and is unique up to isomorphism. By [Reference Lam23, Theorem 3.30 and Exercise 3.6.12], it follows that
$\boldsymbol {I}$
is an injective hull of M if and only if
$\iota (M) \supseteq \mathrm {soc}(\boldsymbol {I})$
. Here
$\mathrm {soc}(\boldsymbol {I})$
is the socle of
$\boldsymbol {I}$
: that is, the sum of all simple submodules of
$\boldsymbol {I}$
. When
$\iota $
is clear in the context, we write
$\Omega ^{-1}(M)$
for
$\mathrm {Coker} (\iota )$
and call it the cosyzygy module of M. An exact sequence
with injective modules
$\boldsymbol {I}_0$
and
$\boldsymbol {I}_1$
is called a minimal injective presentation if the
$H_n(0)$
-module homomorphisms
$\iota : M \rightarrow \boldsymbol {I}_0$
and
$\partial ^1: \Omega ^{-1}(M) \rightarrow \boldsymbol {I}_1$
are injective hulls of M and
$\Omega ^{-1}(M)$
, respectively.
We first describe an injective hull of
$\mathcal {V}_{\alpha }$
. Let
$$ \begin{align*} \mathcal{K}(\alpha) := \{1 \leq i \leq \ell(\alpha) \mid \alpha_i> 1\} \cup \{0\}. \end{align*} $$
We write the elements of
$\mathcal {K}(\alpha )$
as
$k_0:=0 < k_1 < k_2 < \cdots < k_m$
. Let
$$ \begin{align*} \underline{{\boldsymbol{\unicode{x3b1}}}} &:= (\alpha_{k_1} -1) \oplus (\alpha_{k_2}-1) \oplus \cdots \oplus \left((\alpha_{k_m}-1) \odot (1^{\ell(\alpha)})\right) \\ & \ = (\alpha_{k_1} -1) \oplus (\alpha_{k_2}-1) \oplus \cdots \oplus (\alpha_{k_{m-1}}-1) \oplus (\alpha_{k_m},1^{\ell(\alpha)-1}). \end{align*} $$
Let us depict
$\mathtt {rd}(\underline {{\boldsymbol {\unicode{x3b1} }}})$
in a pictorial manner. When
$j=0$
, we define
$\mathtt {S}_{k_0}$
to be the vertical strip consisting of all the boxes in the first column of
$\mathtt {cd}(\alpha )$
. For
$1 \le j \le m$
, we define
$\mathtt {S}_{k_j}$
as the horizontal strip consisting of the boxes in the
$k_j$
th row of
$\mathtt {cd}(\alpha )$
(from the top), except for the leftmost box. Then
$\underline {{\boldsymbol {\unicode{x3b1} }}}$
is defined by the generalised composition obtained by placing
$\mathtt {S}_{k_0},\mathtt {S}_{k_1},\ldots , \mathtt {S}_{k_m}$
in the following manner:
-
(i)
$\mathtt {S}_{k_0}$
is placed horizontally at the topmost row in the new diagram. -
(ii)
$\mathtt {S}_{k_m}$
is placed vertically to the lower-left of
$\mathtt {S}_{k_0}$
so that
$\mathtt {S}_{k_0}$
and
$\mathtt {S}_{k_m}$
are connected. -
(iii) For
$j=m-1,m-2, \ldots , 1$
, place
$\mathtt {S}_{k_j}$
vertically to the lower-left of
$\mathtt {S}_{k_{j+1}}$
so that they are not connected to each other.
Figure 2 illustrates the above procedure.
Figure 2 The construction of
$\mathtt {rd}( \underline {{\boldsymbol {\unicode{x3b1} }}})$
when
$\alpha =(2,1,3^2,1)$
.
For simplicity, we introduce the following notation:
-
• For an SIT
$\mathscr {T}$
and a subdiagram
$\mathtt {S}$
of shape of
$\mathscr {T}$
, we denote by
$\mathscr {T}(\mathtt {S})$
the set of entries of
$\mathscr {T}$
in
$\mathtt {S}$
. -
• For an SRT T and a subdiagram
$\mathtt {S}$
of shape of T, we denote by
$T(\mathtt {S})$
the set of entries of T in
$\mathtt {S}$
.
For
$\mathscr {T} \in \mathrm {SIT}(\alpha )$
, let
${T^{\mathscr {T}}}$
be the tableau of
$\mathtt {rd}(\underline {{\boldsymbol {\unicode{x3b1} }}})$
defined by
$$ \begin{align*} ({T^{\mathscr{T}}})(\mathtt{S}_{k_j}) := \mathscr{T}(\mathtt{S}_{k_j}) \qquad \text{for } 0 \leq j \leq m. \end{align*} $$
Extending the assignment
$\mathscr {T} \mapsto T^{\mathscr {T}}$
by linearity, we define the
$\mathbb C$
-linear map
$$ \begin{align*} \epsilon: \mathcal{V}_{\alpha} \rightarrow \mathbf{P}_{\underline{{\boldsymbol{\unicode{x3b1}}}}}, \quad \mathscr{T} \mapsto {T^{\mathscr{T}}}, \end{align*} $$
which is obviously injective.
Theorem 4.1 (This will be proven in Subsection 6.2).
$\epsilon : \mathcal {V}_{\alpha } \to \mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}}$
is an injective hull of
$\mathcal {V}_{\alpha }$
.
For later use, we provide bases of
$\epsilon (\mathcal {V}_{\alpha })$
and
$\Omega ^{-1}(\mathcal {V}_{\alpha })$
. From the injectivity of
$\epsilon $
, we derive that
$\epsilon (\mathcal {V}_{\alpha })$
is spanned by
$$ \begin{align*} \{ T \in \mathrm{SRT}(\underline{{\boldsymbol{\unicode{x3b1}}}}) \mid T_j^{1+\delta_{j,m}}> T^1_{m+k_j-1} \text{ for all } 1\leq j \leq m\} \end{align*} $$
and
$\Omega ^{-1}(\mathcal {V}_{\alpha })$
is spanned by
$\{T + \epsilon (\mathcal {V}_{\alpha }) \mid T \in \Theta (\mathcal {V}_{\alpha })\}$
with
$$ \begin{align} \Theta(\mathcal{V}_{\alpha}) := \{ T \in \mathrm{SRT}(\underline{{\boldsymbol{\unicode{x3b1}}}}) \mid T_j^{1+\delta_{j,m}} < T^1_{m+k_j-1} \text{ for some }1\leq j \leq m \}. \end{align} $$
Example 4.2. If
$\alpha = (1,2,2) \models 5$
, then
$\mathcal {K}(\alpha ) = \{0,2,3\}$
and
$\underline {{\boldsymbol {\unicode{x3b1} }}} = (1)\oplus (2,1^2)$
. For
, one sees that
. The map
$\epsilon :\mathcal {V}_{\alpha } \rightarrow \mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}}$
is illustrated in Figure 3, where the red entries i in tableaux are used to indicate that
$\pi _i$
acts on them as zero.
Figure 3
$\epsilon : \mathcal {V}_{(1,2,2)} \rightarrow \mathbf {P}_{(1)\oplus (2,1,1)}$
.
We next describe an injective hull of
$\Omega ^{-1}(\mathcal {V}_{\alpha })$
. To do this, we need an
$H_n(0)$
-module homomorphism
$\partial ^1: \mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}}\rightarrow \boldsymbol {I}$
with
$\boldsymbol {I}$
an injective module satisfying that
$\ker (\partial ^1)=\epsilon (\mathcal {V}_{\alpha })$
.
First, we provide the required injective module
$\boldsymbol {I}$
. For
$1 \leq j \leq m$
, define
$\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}$
to be the generalised composition
$$ \begin{align*} \underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}: = \left\{ \begin{array}{ll} (\alpha_{k_1}-1) \oplus \cdots \oplus (\alpha_{k_j} - 2) \oplus \cdots \oplus (\alpha_{k_m}, 1^{\ell(\alpha)-k_j+1}) \oplus (1^{k_j-1}) & \quad \text{if } 1 \leq j < m, \\ (\alpha_{k_1}-1 ) \oplus \cdots \oplus (\alpha_{k_{m-1}}-1) \oplus \left((\alpha_{k_m}-1,1^{\ell(\alpha)-k_j+1}) \cdot (1^{k_j-1})\right) & \quad \text{if } j = m. \end{array} \right. \end{align*} $$
Then we set
$$ \begin{align} \boldsymbol{I}:=\bigoplus_{1 \leq j \leq m}\mathbf{P}_{\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}. \end{align} $$
In the following, we provide a pictorial description of
$\mathtt {rd}(\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)})$
. We begin by recalling that
$\mathtt {rd}(\underline {{\boldsymbol {\unicode{x3b1} }}})$
consists of the horizontal strip
$\mathtt {S}_{k_0}$
and the vertical strips
$\mathtt {S}_{k_1},\ldots ,\mathtt {S}_{k_m}$
. For each
$-1\le r \le m$
, we denote by
$\mathtt {S}^{\prime }_{k_r}$
the connected horizontal strip of length
$$ \begin{align*} |\mathtt{S}^{\prime}_{k_r}|:= \begin{cases} k_j-1 & \text{ if } r = -1,\\ \ell(\alpha)-k_j+2 & \text{ if } r = 0, \\ |\mathtt{S}_{k_r}| - \delta_{r,j} & \text{ if } 1 \leq r \leq m, \end{cases} \end{align*} $$
where
$k_{-1} := -1$
. With this preparation,
$\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}$
is defined to be the generalised composition obtained by placing
$\mathtt {S}^{\prime }_{k_{-1}},\mathtt {S}^{\prime }_{k_0},\mathtt {S}^{\prime }_{k_1},\ldots ,\mathtt {S}^{\prime }_{k_m}$
in the following way:
-
(i)
$\mathtt {S}^{\prime }_{k_1}$
is placed vertically to the leftmost column in the diagram we will create. -
(ii) For
$j = 2,3,\ldots , m$
,
$\mathtt {S}^{\prime }_{k_j}$
is placed vertically to the upper-right of
$\mathtt {S}^{\prime }_{k_{j-1}}$
so that they are not connected to each other. -
(iii)
$\mathtt {S}^{\prime }_{k_0}$
is placed horizontally to
$\mathtt {S}^{\prime }_{k_m}$
so that they are connected. -
(iv) In the case where
$j \neq m$
,
$\mathtt {S}^{\prime }_{k_{-1}}$
is placed horizontally to the upper-right of
$\mathtt {S}^{\prime }_{k_0}$
so that they are disconnected. In the case where
$j = m$
,
$\mathtt {S}^{\prime }_{k_{-1}}$
is placed horizontally to the upper-right of
$\mathtt {S}^{\prime }_{k_0}$
so that they are connected.
Figure 4 illustrates the above procedure.
Figure 4 The construction of
$\mathtt {rd}(\underline {{\boldsymbol {\unicode{x3b1} }}}_{(1)})$
and
$\mathtt {rd}(\underline {{\boldsymbol {\unicode{x3b1} }}}_{(2)})$
when
$\alpha = (1,3,2,1)$
.
Now, let us construct
$\partial ^1: \mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}}\rightarrow \boldsymbol {I}$
. Choose any tableau T in
$\mathrm {SRT}(\underline {{\boldsymbol {\unicode{x3b1} }}})$
. Recall that
$\mathbf {w}(T)$
is the word obtained by reading the entries of T from left to right, starting with the bottom row. Let
$\mathbf {w}(T) = w_1 w_2 \cdots w_n$
. For each
$1 \leq j \leq m$
, we consider the subword
$\mathbf {w}_{T;j}$
of
$\mathbf {w}(T)$
defined by
$$ \begin{align} \mathbf{w}_{T;j} := w_{u_1(j)} w_{u_2(j)} \cdots w_{u_{l_j}(j)}, \end{align} $$
where the subscripts
$u_i(j)$
s are defined via the following recursion:
$$ \begin{align*} &u_1(j) = \sum_{1 \le r \le j} (\alpha_{k_r}-1),\\ &u_{i+1}(j) = \min \{u_i(j) < u \le n - \ell(\alpha) \mid w_u < w_{u_i(j)} \} \quad (i \ge 1), \text{ and }\\ &l_j := \max \{i \mid u_i(j) < \infty \}. \end{align*} $$
In the second identity, whenever
$\{u_i(j) < u \le n - \ell (\alpha ) \mid w_u < w_{u_i(j)} \}=\emptyset $
, we set
$u_{i+1}(j):=\infty $
. Henceforth we simply write
$u_i$
s for
$u_i(j)$
s and thus
$\mathbf {w}_{T;j}= w_{u_1} w_{u_2} \cdots w_{u_{l_j}}$
. Given an arbitrary word w, we use
$\textsf {end}(w)$
to denote the last letter of w. With the notations above, we introduce the following two sets:
$$ \begin{align*} \begin{aligned} \mathtt{A}_{T;j} &: = \{y \in T(\mathtt{S}_{k_0}) \mid y> \textsf{end}(\mathbf{w}_{T;j})\}, \\ \mathcal{P}(\mathtt{A}_{T;j}) &: = \left\{ A \subseteq \mathtt{A}_{T;j} \mid |A| = \ell(\alpha)-k_j+1 \right\}. \end{aligned} \end{align*} $$
For
$A \in \mathcal {P}(\mathtt {A}_{T;j})$
, we define
$\tau _{T;j;A}$
to be an SRT of shape
$\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}$
that is uniquely determined by the following conditions:
-
(i)
$\tau _{T;j;A}(\mathtt {S}^{\prime }_{k_{-1}}) = T(\mathtt {S}_{k_0}) \setminus A$
, -
(ii)
$\tau _{T;j;A}(\mathtt {S}^{\prime }_{k_0}) =\{\textsf {end}(\mathbf {w}_{T;j})\} \cup A$
, -
(iii)
$\tau _{T;j;A}(\mathtt {S}^{\prime }_{k_r}) = T(\mathtt {S}_{k_r})$
for
$1 \leq r < j$
, -
(iv)
$\tau _{T;j;A}(\mathtt {S}^{\prime }_{k_j}) = T(\mathtt {S}_{k_j}) \setminus \{w_{u_1} \}$
, and -
(v) for
$j < r \leq m$
,
$\tau _{T;j;A}(\mathtt {S}^{\prime }_{k_r})$
is obtained from
$T(\mathtt {S}_{k_r})$
by substituting
$w_{u_{i}}$
with
$w_{u_{i-1}}$
for
$w_{u_{i}}$
s (
$1 < i \le l_j$
) contained in
$T(\mathtt {S}_{k_r})$
.
We next explain the notion of the signature
$\mathrm {sgn}(A)$
of A. Enumerate the elements in
$\mathtt {A}_{T;j}$
in the increasing order
$$\begin{align*}a_1 < a_2 < \cdots < a_{|\mathtt{A}_{T;j}|}. \end{align*}$$
Then let
$A^1_{T;j}$
be the set of the consecutive
$(\ell (\alpha )-k_j+1)$
elements starting from the rightmost and moving to the left, precisely,
$$ \begin{align*} A^1_{T;j} = \{a_{|\mathtt{A}_{T;j}|-\ell(\alpha)+k_j},a_{|\mathtt{A}_{T;j}|-\ell(\alpha)+k_j+1}, \ldots,a_{|\mathtt{A}_{T;j}|} \}. \end{align*} $$
There is a natural right
$\Sigma _{|\mathtt {A}_{T;j}|}$
-action on
$\mathtt {A}_{T;j}$
given by
$$ \begin{align} a_i \cdot \omega = a_{\omega^{-1}(i)} \text{ for } 1 \le i \le |\mathtt{A}_{T;j}| \text{ and }\omega \in \Sigma_{|\mathtt{A}_{T;j}|}. \end{align} $$
We define
$\mathrm {sgn}(A) := (-1)^{\ell (\omega ^1)}$
, where
$\omega ^1$
is any minimal length permutation in
$\{\omega \in \Sigma _{|\mathtt {A}_{T;j}|} \mid A = A^1_{T;j} \cdot \omega \}$
.
For each
$1 \leq j \leq m$
, set
$$ \begin{align*} {\boldsymbol{\tau}}_{T;j}:= \displaystyle \sum_{A \in \mathcal{P}(\mathtt{A}_{T;j})} \mathrm{sgn}(A) \tau_{T;j;A}, \end{align*} $$
where the summation in the right-hand side is zero in the case where
$\mathcal {P}(\mathtt {A}_{T;j})=\emptyset $
. Finally, we define a
$\mathbb C$
-linear map
$$ \begin{align*} \partial^1: \mathbf{P}_{\underline{{\boldsymbol{\unicode{x3b1}}}}}\rightarrow \boldsymbol{I}, \quad T \mapsto \sum_{1 \leq j \leq m} {\boldsymbol{\tau}}_{T;j} \end{align*} $$
with
$\boldsymbol {I}$
in equation (4.2).
Theorem 4.3 (This will be proven in Subsection 6.3).
Let
$\alpha $
be a composition of n.
-
(a)
$\partial ^1: \mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}} \rightarrow \boldsymbol {I}$
is an
$H_n(0)$
-module homomorphism. -
(b) The sequence
is exact. -
(c) The
$H_n(0)$
-module homomorphism induced from
$$\begin{align*}\overline{\partial^1}: \Omega^{-1}(\mathcal{V}_{\alpha}) \rightarrow \boldsymbol{I}, \quad T + \epsilon(\mathcal{V}_{\alpha}) \mapsto \partial^1(T) \quad (T \in \Theta(\mathcal{V}_{\alpha})) \end{align*}$$
$\partial ^1$
is an injective hull of
$\Omega ^{-1}(\mathcal {V}_{\alpha })$
.
-
(d) Let
$\mathcal {L}(\alpha ) := \bigcup _{1 \leq j \leq m} [\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}]$
, which is viewed as a multiset. Then we have where
$$\begin{align*}\mathrm{Ext}_{H_n(0)}^1(\mathbf{F}_{\beta},\mathcal{V}_{\alpha}) \cong \begin{cases} \mathbb C^{[\mathcal{L}(\alpha):\beta^{\mathrm{r}}]} & \text{ if } \beta^{\mathrm{r}} \in \mathcal{L}(\alpha)\\ 0 & \text{otherwise,} \end{cases} \end{align*}$$
$[\mathcal {L}(\alpha ):\beta ^{\mathrm {r}}]$
denotes the multiplicity of
$\beta ^{\mathrm {r}}$
in
$\mathcal {L}(\alpha )$
.
Example 4.4. Let
$\alpha = (2,1,2,3) \models 8$
. Then
$\mathcal {K}(\alpha ) = \{0,1,3,4\}$
and
$\underline {{\boldsymbol {\unicode{x3b1} }}} = (1) \oplus (1) \oplus (3,1^3)$
. By definition, we get
$$ \begin{align*} \underline{{\boldsymbol{\unicode{x3b1}}}}_{(1)} & = (1) \oplus (3,1^4), \\ \underline{{\boldsymbol{\unicode{x3b1}}}}_{(2)} & = (1) \oplus (3,1^2) \oplus (1^2), \\ \underline{{\boldsymbol{\unicode{x3b1}}}}_{(3)} & = (1) \oplus (1) \oplus (2^2,1^2). \end{align*} $$
(a) Let
. Then one sees that
$$ \begin{align*} \begin{array}{llll} \mathbf{w}_{T;1} = 6 \ 2 \quad & \quad \textsf{end}(\mathbf{w}_{T;1}) = 2 \quad & \mathtt{A}_{T;1} = \{3, 7,8\} \quad & \quad \mathcal{P}(\mathtt{A}_{T;1}) = \emptyset,\\ \mathbf{w}_{T;2} = 2 & \quad \textsf{end}(\mathbf{w}_{T;2}) = 2 & \mathtt{A}_{T;2} = \{3,7,8 \} & \quad \mathcal{P}(\mathtt{A}_{T;2}) = \{\{3,7\},\{3,8\},\{7,8\}\}, \\ \mathbf{w}_{T;3} = 4 & \quad \textsf{end}(\mathbf{w}_{T;3}) = 4 & \mathtt{A}_{T;3} = \{7,8 \} & \quad \mathcal{P}(\mathtt{A}_{T;3}) = \{\{7\},\{8\} \}. \end{array} \end{align*} $$
Since
it follows that
$$ \begin{align*} {\boldsymbol{\tau}}_{T;1} = 0 \qquad {\boldsymbol{\tau}}_{T;2} = \tau_{T;2;\{3,7\}} - \tau_{T;2;\{3,8\}} + \tau_{T;2;\{7,8\}} \qquad {\boldsymbol{\tau}}_{T;3} = - \tau_{T;3;\{7\}} + \tau_{T;3;\{8\}}. \end{align*} $$
Therefore,
$$ \begin{align*} \partial^1(T) = (\tau_{T;2;\{3,7\}} - \tau_{T;2;\{3,8\}} + \tau_{T;2;\{7,8\}}) + (- \tau_{T;3;\{7\}} + \tau_{T;3;\{8\}}). \end{align*} $$
(b) Note that
$$ \begin{align*} [\underline{{\boldsymbol{\unicode{x3b1}}}}_{(1)}] & = \left\{(1,3,1^4), (4,1^4)\right\}, \\ [\underline{{\boldsymbol{\unicode{x3b1}}}}_{(2)}] & = \left\{(1,3,1^4),(1,3,1,2,1),(4,1^4),(4,1,2,1)\right\}, \\ [\underline{{\boldsymbol{\unicode{x3b1}}}}_{(3)}] & = \left\{(1^2,2^2,1^2),(1,3,2,1^2),(2^3,1^2),(4,2,1^2) \right\}. \end{align*} $$
Theorem 4.3(d) implies that
$$ \begin{align*} \dim \mathrm{Ext}^1_{H_n(0)}(\mathbf{F}_{\beta},\mathcal{V}_{\alpha}) = \begin{cases} 1 & \text{ if } \beta^{\mathrm{r}} \in \mathcal{L}(\alpha) \setminus \{(1, 3, 1^4),(4, 1^4)\}, \\ 2 & \text{ if } \beta^{\mathrm{r}} \in \{(1,3,1^4), (4, 1^4)\}, \\ 0 & \text{ otherwise.} \end{cases} \end{align*} $$
5
$\mathrm {Ext}^i_{H_n(0)}(\mathcal {V}_{\alpha }, \mathcal {V}_{\beta })$
with
$i=0,1$
In the previous sections, we computed
$\mathrm {Ext}^1_{H_n(0)}(\mathcal {V}_{\alpha }, \mathbf {F}_{\beta })$
and
$\mathrm {Ext}^1_{H_n(0)}(\mathbf {F}_{\beta }, \mathcal {V}_{\alpha })$
. In this section, we focus on
$\mathrm {Ext}^1_{H_n(0)}(\mathcal {V}_{\alpha }, \mathcal {V}_{\beta })$
and
$\mathrm {Ext}^0_{H_n(0)}(\mathcal {V}_{\alpha }, \mathcal {V}_{\beta })\, (=\mathrm {Hom}_{H_n(0)}(\mathcal {V}_{\alpha }, \mathcal {V}_{\beta }))$
.
Let
$M, N$
be finite-dimensional
$H_n(0)$
-modules. Given a short exact sequence
with
$(P_0,\pi )$
a projective cover of M, it is well known that
$$ \begin{align*} \mathrm{Ext}_{H_n(0)}^1(M,N) \cong \frac{\mathrm{Hom}_{H_n(0)}(\Omega(M),N)} {\mathrm{Im} \,\iota^{\ast}}, \end{align*} $$
where
$\iota ^{\ast}\!:\mathrm {Hom}_{H_n(0)}(P_0, N) \to \mathrm {Hom}_{H_n(0)}(\Omega (M),N)$
is given by composition with
$\iota $
. The kernel of
$\iota ^{\ast }$
equals
$$\begin{align*}\{f\in \mathrm{Hom}_{H_n(0)}(P_0,N) \mid f|_{\Omega(M)}=0\}, \end{align*}$$
and therefore
$$ \begin{align} \ker(\iota^{\ast}) \cong \mathrm{Hom}_{H_n(0)}(P_0/\Omega(M),N)\cong \mathrm{Hom}_{H_n(0)}(M,N). \end{align} $$
This says that
$\mathrm {Ext}_{H_n(0)}^1(M,N)=0$
if and only if, as
$\mathbb C$
-vector spaces,
$$ \begin{align} \mathrm{Hom}_{H_n(0)}(P_0, N) \cong \mathrm{Hom}_{H_n(0)}(\Omega(M), N) \oplus \mathrm{Hom}_{H_n(0)}(M,N). \end{align} $$
Definition 5.1. Given a finite-dimensional
$H_n(0)$
-module M, we say that M is rigid if
$\mathrm {Ext}_{H_n(0)}^1 (M,M)=0$
and essentially rigid if
$\mathrm {Hom}_{H_n(0)}(\Omega (M),M)=0$
.
Whenever M is essentially rigid, one has that
$\mathrm {Hom}_{H_n(0)}(P_0, M) \cong \mathrm {End}_{H_n(0)}(M).$
Typical examples of essentially rigid
$H_n(0)$
-modules are simple modules and projective modules. The syzygy and cosyzygy modules of a rigid module are also rigid since
$\mathrm {Ext}_{H_n(0)}^1(M,N)=\mathrm {Ext}_{H_n(0)}^1(\Omega (M),\Omega (N))$
and
$M \cong \Omega \Omega ^{-1}(M) \oplus (\mathrm {projective})$
(for example, see [Reference Benson3]).
Let us use
$\le _l$
to represent the lexicographic order on compositions of n. Using the results in the preceding sections, we derive some interesting results on
$\mathrm {Ext}_{H_n(0)}^1(\mathcal {V}_{\alpha },\mathcal {V}_{\beta })$
. To do this, we need the following lemmas.
Lemma 5.2 ([Reference Benson3, Lemma 1.7.6]).
Let M be a finite-dimensional
$H_n(0)$
-module. Then
$\dim \mathrm {Hom}_{H_n(0)}( \mathbf {P}_{\alpha }, M)$
is the multiplicity of
$\mathbf {F}_{\alpha }$
as a composition factors of M.
Lemma 5.3 ([Reference Berg, Bergeron, Saliola, Serrano and Zabrocki4, Proposition 3.37]).
The dual immaculate functions
$\mathfrak {S}^*_{\alpha }$
are fundamental positive. Specifically, they expand as
$\mathfrak {S}^*_{\alpha }=\sum _{\beta \le _l \alpha }L_{\alpha , \beta }F_{\beta }$
, where
$L_{\alpha , \beta }$
denotes the number of standard immaculate tableaux
$\mathscr {T}$
of shape
$\alpha $
and descent composition
$\beta $
: that is,
$\mathrm {comp}(\mathrm {Des}(\mathscr {T})) = \beta $
.
We now state the main result of this section.
Theorem 5.4. Let
$\alpha $
be a composition of n.
-
(a) For all
$\beta \le _l \alpha $
,
$\mathrm {Ext}_{H_n(0)}^1(\mathcal {V}_{\alpha },\mathcal {V}_{\beta })=0.$
In particular,
$\mathcal {V}_{\alpha }$
is essentially rigid. -
(b) For all
$\beta \le _l \alpha $
, we have
$$\begin{align*}\mathrm{Hom}_{H_n(0)}(\mathcal{V}_{\alpha}, \mathcal{V}_{\beta}) \cong\begin{cases} \mathbb C & \text{if } \beta =\alpha,\\ 0 & \text{otherwise.} \end{cases} \end{align*}$$
-
(c) Let M be any nonzero quotient of
$\mathcal {V}_{\alpha }$
. Then
$\mathrm {End}_{H_n(0)}(M) \cong \mathbb C$
.
Proof. (a) Due to Theorem 3.3, there is a projective resolution of
$\mathcal {V}_{\alpha }$
of the form
Hence, for the assertion, it suffices to show that
$$\begin{align*}\mathrm{Hom}_{H_n(0)}\left(\bigoplus_{i \in \mathcal{I}(\alpha)} \mathbf{P}_{{\boldsymbol{\unicode{x3b1}}}^{(i)}},\mathcal{V}_{\beta} \right)=0. \end{align*}$$
Observe that
$$ \begin{align*} \dim\mathrm{Hom}_{H_n(0)}\left(\bigoplus_{i \in \mathcal{I}(\alpha)} \mathbf{P}_{{\boldsymbol{\unicode{x3b1}}}^{(i)}},\mathcal{V}_{\beta} \right) &=\sum_{ \gamma \in \mathcal{J}(\alpha)}\dim\mathrm{Hom}_{H_n(0)}\left(\mathbf{P}_{\gamma},\mathcal{V}_{\beta} \right)\\ &=\sum_{ \gamma \in \mathcal{J}(\alpha)} [\mathcal{V}_{\beta}:\mathbf{F}_{\gamma}] \quad \text{ (by Lemma \hyperlink{lemma1}{5.2})}. \end{align*} $$
Here,
$[\mathcal {V}_{\beta }:\mathbf {F}_{\gamma }]$
denotes the multiplicity of
$\mathbf {F}_{\gamma }$
as a composition factor of
$\mathcal {V}_{\beta }$
and thus equals the coefficient of
$F_{\gamma }$
in the expansion of
$\mathfrak {S}^*_{\beta }$
into fundamental quasisymmetric functions. From Lemma 5.3, it follows that this coefficient vanishes unless
$\beta \ge _l \gamma $
. Since
$\alpha <_l \gamma $
for all
$\gamma \in \mathcal {J}(\alpha )$
, the assumption
$\beta \le _l \alpha $
yields the desired result.
(b) Combining equation (5.2) with (a) yields that
$$ \begin{align*} \mathrm{Hom}_{H_n(0)}(\mathbf{P}_{\alpha}, \mathcal{V}_{\beta})\cong \mathrm{Hom}_{H_n(0)}(\Omega(\mathcal{V}_{\alpha}), \mathcal{V}_{\beta}) \oplus \mathrm{Hom}_{H_n(0)}(\mathcal{V}_{\alpha},\mathcal{V}_{\beta}). \end{align*} $$
But by Lemma 5.2 and Lemma 5.3, we see that
$$ \begin{align*} \dim\mathrm{Hom}_{H_n(0)}(\mathbf{P}_{\alpha}, \mathcal{V}_{\beta})=L_{\beta, \alpha}= \begin{cases} 1 & \text{ if } \beta =\alpha\\ 0 & \text{ otherwise.} \end{cases} \end{align*} $$
This justifies the assertion since
$\dim \mathrm {End}_{H_n(0)}( \mathcal {V}_{\alpha })\ge 1$
.
(c) Let
$f:\mathbf {P}_{\alpha } \to M$
be a surjective
$H_n(0)$
-module homomorphism. Then
$$\begin{align*}\mathrm{End}_{H_n(0)}(M)\cong \mathrm{Hom}_{H_n(0)}(\mathbf{P}_{\alpha}/\ker(f), M), \end{align*}$$
and therefore
$$\begin{align*}1\le \dim\mathrm{End}_{H_n(0)}(M)\le \dim\mathrm{Hom}_{H_n(0)}(\mathbf{P}_{\alpha}, M)=[M: \mathbf{F}_{\alpha}]. \end{align*}$$
Now the assertion follows from the inequality
$[M: \mathbf {F}_{\alpha }]\le [\mathcal {V}_{\alpha }: \mathbf {F}_{\alpha }]=L_{\alpha , \alpha }=1$
.
Remark 5.5. To the best of the authors’ knowledge, the classification or distribution of indecomposable rigid modules is completely unknown. For the reader’s understanding, we provide some related examples.
-
(a) Let
. A simple computation shows that M is a rigid indecomposable module. But since
$\dim \mathrm {Hom}_{H_5(0)}(\Omega (M), M) = 1$
, it is not essentially rigid. -
(b) Let
. By adding two Vs appropriately, one can produce a nonsplit sequence Hence V is a nonrigid indecomposable module.
Theorem 5.4 (b) is no longer valid unless
$\beta \le _l \alpha $
. In view of
$\mathcal {V}_{\alpha } \cong \mathbf {P}_{\alpha } / \Omega (\mathcal {V}_{\alpha })$
, one can view
$\mathrm {Hom}_{H_n(0)}(\mathcal {V}_{\alpha },\mathcal {V}_{\beta })$
as the
$\mathbb C$
-vector space consisting of
$H_n(0)$
-module homomorphisms from
$\mathbf {P}_{\alpha }$
to
$\mathcal {V}_{\beta }$
that vanish on
$\Omega (\mathcal {V}_{\alpha })$
. Therefore, to understand
$\mathrm {Hom}_{H_n(0)}(\mathcal {V}_{\alpha },\mathcal {V}_{\beta })$
, it is indispensable to understand
$\mathrm {Hom}_{H_n(0)}(\mathbf {P}_{\alpha }, \mathcal {V}_{\beta })$
first. To do this, let us fix a linear extension
$\preccurlyeq _{L}^{\mathrm {r}}$
of the partial order
$\preccurlyeq ^{\mathrm {r}}$
on
$\mathrm {SIT}(\beta )$
given by
$$ \begin{align*} \tau' \preccurlyeq^{\mathrm{r}}\tau \quad \text{if and only if} \quad \tau' = \pi_{\gamma} \cdot \tau \text{ for some } \gamma\in\Sigma_n. \end{align*} $$
Given
$f\in \mathrm {Hom}_{H_n(0)}(\mathbf {P}_{\alpha },\mathcal {V}_{\beta })$
, let
$f(T_{\alpha })=\sum _{\mathscr {T} \in \mathrm {SIT}(\beta )}c_{f,\mathscr {T}}\mathscr {T}$
. We define
${\mathsf {Lead}}(f)$
to be the largest tableau in
$\{\mathscr {T} \in \mathrm {SIT}(\beta ): c_{f,\mathscr {T}}\ne 0\}$
with respect to
$\preccurlyeq _{L}^{\mathrm {r}}$
. When
$f=0$
,
${\mathsf {Lead}}(f)$
is set to be
$\emptyset $
.
Theorem 5.6. Let
$\alpha , \beta $
be compositions of n, and let
${\mathfrak B}$
be the set of standard immaculate tableaux U of shape
$\beta $
with
$\mathrm {Des}(U)=\mathrm {set}(\alpha )$
.
-
(a) For each standard immaculate tableau U of shape
$\beta $
with
$\mathrm {Des}(U)=\mathrm {set}(\alpha )$
, there exists a unique homomorphism
$f_U\in \mathrm {Hom}_{H_n(0)}(\mathbf {P}_{\alpha },\mathcal {V}_{\beta })$
such that
${\mathsf {Lead}}(f)=U$
,
$c_{f,U}=1$
and
$c_{f,U'}=0$
for all
$U'\in {\mathfrak B}\setminus \{U\}$
. -
(b) The dimension of
$\mathrm {Hom}_{H_n(0)}(\mathcal {V}_{\alpha },\mathcal {V}_{\beta })$
is the same as the dimension of
$$\begin{align*}\{(c_U)_{U\in {\mathfrak B}} \in \mathbb C^{|{\mathfrak B}|}: \sum_{U}c_U \,\pi_{[m_{i-1} + 1, m_i]} \cdot f_U(T_{\alpha})=0 \text{ for all } i \in \mathcal{I}(\alpha) \}. \end{align*}$$
Proof. (a) Observe that every homomorphism in
$\mathrm {Hom}_{H_n(0)}(\mathbf {P}_{\alpha },\mathcal {V}_{\beta })$
is completely determined by the value at the source tableau
$T_{\alpha }$
of
$\mathbf {P}_{\alpha }$
. We claim that
$\mathrm {Des}({\mathsf {Lead}}(f)) =\mathrm {set}(\alpha )$
for all nonzero
$f\in \mathrm {Hom}_{H_n(0)}(\mathbf {P}_{\alpha },\mathcal {V}_{\beta })$
. To begin with, from the equalities
$f(\pi _i \cdot T_{\alpha })=f(T_{\alpha })$
for all
$i\notin \mathrm {Des}(T_{\alpha })=\mathrm {set}(\alpha )$
, we see that f satisfies the condition that
$\mathrm {Des}({\mathsf {Lead}}(f)) \subseteq \mathrm {set}(\alpha )$
. Recall that we set
$m_i:=\sum _{1\le k \le i}\alpha _i$
for all
$1\le i \le \ell (\alpha )$
in Section 3. Suppose that there is an index j such that
$$\begin{align*}m_j \in \mathrm{set}(\alpha) \setminus \mathrm{Des}({\mathsf {Lead}}(f)). \end{align*}$$
Then
$$\begin{align*}m_{j-1}+1, m_{j-1}+2, \ldots, m_{j+1}-1 \in \mathrm{set}(\alpha) \setminus \mathrm{Des}({\mathsf {Lead}}(f)). \end{align*}$$
But this is absurd since
$$\begin{align*}\pi_{[m_{j-1}+1, m_{j+1}-\alpha_j]^{\mathrm{r}}} \cdots \pi_{[m_j-1,m_{j+1}-2]^{\mathrm{r}}}\pi_{[m_j, m_{j+1}-1]^{\mathrm{r}}} \cdot T_{\alpha} = 0, \end{align*}$$
whereas
$$\begin{align*}\pi_{[m_{j-1}+1, m_{j+1}-\alpha_j]^{\mathrm{r}}} \cdots \pi_{[m_j-1,m_{j+1}-2]^{\mathrm{r}}}\pi_{[m_j, m_{j+1}-1]^{\mathrm{r}}} \cdot {\mathsf {Lead}}(f) = {\mathsf {Lead}}(f). \end{align*}$$
So the claim is verified.
For each
$U \in {\mathfrak B}$
, consider the
$\mathbb C$
-vector space
$$ \begin{align*} H(U):=\{f\in \mathrm{Hom}_{H_n(0)}(\mathbf{P}_{\alpha},\mathcal{V}_{\beta}): {\mathsf {Lead}}(f) \preccurlyeq_{L}^{\mathrm{r}} U\}. \end{align*} $$
Write
${\mathfrak B}$
as
$\{U_1\preccurlyeq _{L}^{\mathrm {r}}U_{2} \preccurlyeq _{L}^{\mathrm {r}} \cdots \preccurlyeq _{L}^{\mathrm {r}} U_{l-1} \preccurlyeq _{L}^{\mathrm {r}} U_{l}\}$
, where
$l=|{\mathfrak B}|$
. For any
$f,g \in H(U_i)$
, it holds that
$$\begin{align*}c_{g,{\mathsf {Lead}}(g)}f- c_{f,{\mathsf {Lead}}(f)}g \in H(U_{i-1}) \end{align*}$$
with
$H(U_0):=0$
. This implies that
$\dim H(U_i)/H(U_{i-1}) \le 1$
for all
$1\le i \le l$
.
Combining these inequalities with the equality
$\dim \mathrm {Hom}_{H_n(0)}\left (\mathbf {P}_{\alpha },\mathcal {V}_{\beta } \right )=|{\mathfrak B}|$
, we deduce that, for each
$U\in {\mathfrak B}$
, there exists a unique
$f_U\in \mathrm {Hom}_{H_n(0)}(\mathbf {P}_{\alpha },\mathcal {V}_{\beta })$
with the desired property.
(b) By (a), one sees that
$\{f_U: U\in {\mathfrak B}\}$
forms a basis for
$\mathrm {Hom}_{H_n(0)}\left (\mathbf {P}_{\alpha },\mathcal {V}_{\beta } \right )$
. Since
$\mathrm {Hom}_{H_n(0)}(\mathcal {V}_{\alpha },\mathcal {V}_{\beta })$
is isomorphic to the
$\mathbb C$
-vector space consisting of
$H_n(0)$
-module homomorphisms from
$\mathbf {P}_{\alpha }$
to
$\mathcal {V}_{\beta }$
which vanish on
$\Omega (\mathcal {V}_{\alpha })$
, our assertion follows from Lemma 6.2, which says that
$\{\pi _{[m_{i-1} + 1, m_i]} \cdot T_{\alpha } \,: \, i \in \mathcal {I}(\alpha )\}$
is a generating set of
$\Omega (\mathcal {V}_{\alpha })$
.
Example 5.7. (a) Let
$\alpha =(1,1,2,1)$
and
$\beta =(1,2,2)$
. Then
and
Note that
$\mathcal {I}(\alpha )=\{2\}$
and
$m_1=1, m_2=2$
. Since
$\pi _{2} \cdot f_U(T_{\alpha })=0$
, it follows that
$\mathrm {Hom}_{H_n(0)}(\mathcal {V}_{\alpha },\mathcal {V}_{\beta })$
is
$1$
-dimensional.
(b) Let
$\alpha =(1,1,3,2)$
and
$\beta =(2,3,2)$
. Then
and
$f_{U_i}(T_{\alpha })=U_i$
for
$i=1,2,3$
. Note that
$\mathcal {I}(\alpha )=\{2,3\}$
and
$m_1=1, m_2=2, m_3 = 5$
. Since
$\pi _{2} \cdot f_{U_i}(T_{\alpha }) =0$
for all
$1\le i \le 3$
and
it follows that
$\mathrm {Hom}_{H_n(0)}(\mathcal {V}_{\alpha },\mathcal {V}_{\beta })$
is
$1$
-dimensional.
We end up with an interesting consequence of Theorem 4.3, where we successfully compute
$\mathrm {Ext}_{H_n(0)}^1(\mathbf {F}_{\beta },\mathcal {V}_{\alpha })$
by constructing an injective hull of
$\Omega ^{-1}(\mathcal {V}_{\alpha })$
. To compute it in a different way, let us consider a short exact sequence
Here,
$\iota $
is the natural injection. Then we have
$$ \begin{align} \mathrm{Ext}_{H_n(0)}^1(\mathbf{F}_{\beta},\mathcal{V}_{\alpha}) \cong \frac{\mathrm{Hom}_{H_n(0)}\left({\mathrm{rad}}(\mathbf{P}_{\beta}) ,\mathcal{V}_{\alpha} \right)} {\mathrm{Im}\, \iota^{\ast}}, \end{align} $$
where
$\iota ^{\ast }: \mathrm {Hom}_{H_n(0)}( \mathbf {P}_{\beta } ,\mathcal {V}_{\alpha } )\rightarrow \mathrm {Hom}_{H_n(0)}({\mathrm {rad}}(\mathbf {P}_{\beta }),\mathcal {V}_{\alpha } ) $
is given by composition by with
$\iota $
. By equation (5.1), one has that
$$ \begin{align*} \dim \mathrm{Im}\, \iota^{\ast} &=\dim \mathrm{Hom}_{H_n(0)}\left(\mathbf{P}_{\beta},\mathcal{V}_{\alpha} \right)-\dim \mathrm{Hom}_{H_n(0)}\left(\mathbf{F}_{\beta},\mathcal{V}_{\alpha} \right)\\ &=[\mathcal{V}_{\alpha}:\mathbf{F}_{\beta}]-[\mathrm{soc}(\mathcal{V}_{\alpha}):\mathbf{F}_{\beta}]\\ &=L_{\alpha, \beta}-[[\underline{{\boldsymbol{\unicode{x3b1}}}}]:\beta^{\mathrm{r}}] \quad \text{(by Lemma 5.3 and Theorem 4.1)}, \end{align*} $$
where
$[[\underline {{\boldsymbol {\unicode{x3b1} }}}]:\beta ^{\mathrm {r}}]$
is the multiplicity of
$\beta ^{\mathrm {r}} \in [\underline {{\boldsymbol {\unicode{x3b1} }}}]$
. Comparing Theorem 4.3 with equation (5.3) yields the following result.
Corollary 5.8. Let
$\alpha , \beta $
be compositions of n. Then we have
$$ \begin{align*} \dim \mathrm{Hom}_{H_n(0)}\left({\mathrm{rad}}(\mathbf{P}_{\beta}) ,\mathcal{V}_{\alpha} \right) =L_{\alpha, \beta}-[[\underline{{\boldsymbol{\unicode{x3b1}}}}]:\beta^{\mathrm{r}}]+ [\mathcal{L}(\alpha):\beta^{\mathrm{r}}]. \end{align*} $$
6 Proof of Theorems
6.1 Proof of Theorem 3.3
We first prove that
$\Omega (\mathcal {V}_{\alpha })$
is generated by
$\{T^{(i)}_{\alpha } \mid i \in \mathcal {I}(\alpha )\}$
. By the definition of
$\Phi $
, one can easily derive that
$$ \begin{align*} \Omega(\mathcal{V}_{\alpha}) = \mathbb C \{T \in \mathrm{SRT}(\alpha) \mid T_p^1> T_{p+1}^1 \text{ for some } 1\leq p < \ell(\alpha)\}. \end{align*} $$
Given
$\sigma \in \Sigma _n$
, let
$$\begin{align*}\mathrm{Des}_L(\sigma):= \{i \in [n-1] \mid \ell(s_i \sigma) < \ell(\sigma)\} \ \ \text{and} \ \ \mathrm{Des}_R(\sigma):= \{i \in [n-1] \mid \ell(\sigma s_i) < \ell(\sigma)\}. \end{align*}$$
The left weak Bruhat order
$\preceq _L$
on
$\Sigma _n$
is the partial order on
$\Sigma _n$
whose covering relation
$\preceq _L^c$
is defined as follows:
$\sigma \preceq _L^c s_i \sigma $
if and only if
$i \notin \mathrm {Des}_L(\sigma )$
. It should be remarked that a word of length n can be confused with a permutation in
$\Sigma _n$
if each of
$1,2,\ldots , n$
appears in it exactly once.
The following lemma plays a key role in proving Lemma 6.2.
Lemma 6.1 ([Reference Björner and Brenti8, Proposition 3.1.2 (vi)]).
Suppose that
$i \in \mathrm {Des}_R(\sigma ) \cap \mathrm {Des}_R(\rho )$
. Then
$\sigma \preceq _L \rho $
if and only if
$\sigma s_i \preceq _L \rho s_i$
.
Lemma 6.2. For each
$i \in \mathcal {I}(\alpha )$
,
$H_n(0) \cdot T^{(i)}_{\alpha } = \mathbb C\{T \in \mathrm {SRT}(\alpha ) \mid T_i^1> T_{i+1}^1 \}$
. Thus,
$\Omega (\mathcal {V}_{\alpha }) = \sum _{i\in \mathcal {I}(\alpha )} H_n(0) \cdot T^{(i)}_{\alpha }$
.
Proof. For simplicity, let
$\mathrm {SRT}(\alpha )^{(i)}$
be the set of
$\mathrm {SRT}$
x of shape
$\alpha $
such that the topmost entry in the ith column is greater than that in the
$(i+1)$
st column.
We first show that
$H_n(0) \cdot T^{(i)}_{\alpha }$
is included in the
$\mathbb C$
-span of
$\mathrm {SRT}(\alpha )^{(i)}$
, equivalently
$\pi _{\sigma } \cdot T^{(i)}_{\alpha } \in \mathrm {SRT}(\alpha )^{(i)} \cup \{0\}$
for all
$\sigma \in \Sigma _n$
. Suppose that there exists
$\sigma \in \Sigma _n$
such that
$\pi _{\sigma } \cdot T^{(i)}_{\alpha } \neq 0$
and
$\pi _{\sigma } \cdot T^{(i)}_{\alpha } \notin \mathrm {SRT}(\alpha )^{(i)}$
. Let
$\sigma _0$
be such a permutation with minimal length and j a left descent of
$\sigma _0$
. By the minimality of
$\sigma _0$
, we have
$\pi _{s_j \sigma _0} \cdot T^{(i)}_{\alpha } \in \mathrm {SRT}(\alpha )^{(i)}$
, and therefore
$$\begin{align*}(\pi_{s_j \sigma_0} \cdot T^{(i)}_{\alpha})^1_{i}> (\pi_{s_j \sigma_0} \cdot T^{(i)}_{\alpha})^1_{i+1}.\end{align*}$$
By the definition of the
$\pi _j$
-action on
$\mathrm {SRT}(\alpha )$
, we have
$$\begin{align*}( \pi_j \cdot (\pi_{s_j \sigma_0} \cdot T^{(i)}_{\alpha}) )^1_i> ( \pi_j \cdot (\pi_{s_j \sigma_0} \cdot T^{(i)}_{\alpha}) )^1_{i+1}.\end{align*}$$
However, since
$\pi _j \cdot (\pi _{s_j \sigma _0} \cdot T^{(i)}_{\alpha }) = \pi _{\sigma _0} \cdot T^{(i)}_{\alpha }$
, this contradicts the assumption that
$\pi _{\sigma _0} \cdot T^{(i)}_{\alpha } \notin \mathrm {SRT}(\alpha )^{(i)}$
.
We next show the opposite inclusion
$\mathrm {SRT}(\alpha )^{(i)} \subseteq H_n(0) \cdot T^{(i)}_{\alpha }$
. Our strategy is to use [Reference Huang20, Theorem 3.3], which implicitly says that for
$T_1, T_2 \in \mathrm {SRT}(\alpha )$
,
$T_2 \in H_n(0) \cdot T_1$
if and only if
$\mathbf {w}(T_1) \preceq _L \mathbf {w}(T_2)$
. Here,
$\mathbf {w}(T_i) \,(i=1,2)$
denotes the word obtained from
$T_i$
by reading the entries from left to right starting with the bottom row. For each
$T \in \mathrm {SRT}(\alpha )^{(i)}$
, we define
$\tau _T$
to be the filling of
$\mathtt {rd}({\boldsymbol {\unicode{x3b1} }}^{(i)})$
whose entries in each column are increasing from top to bottom and whose columns are given as follows: for
$1 \le p \le \ell (\alpha )$
,
$$ \begin{align} (\tau_T)_p^{\bullet} = \begin{cases} T_i^{\bullet} \cup \{T_{i+1}^1\} & \text{if } p = i,\\ T_{i+1}^{\bullet} \setminus \{ T_{i+1}^1 \} & \text{if } p = i+1,\\ T_p^{\bullet} & \text{otherwise.}\\ \end{cases} \end{align} $$
The inequality
$(\tau _T)_i^1 < (\tau _T)_{i+1}^{-1}$
shows that
$\tau _T \in \mathrm {SRT}({\boldsymbol {\unicode{x3b1} }}^{(i)})$
. Combining
$$ \begin{align*} \mathbf{w}(\tau_T) = \mathbf{w}(T) s_{m_{i+1} - 1} s_{m_{i+1} - 2} \cdots s_{m_i} \end{align*} $$
with
$\tau _{T^{(i)}_{\alpha }} = T_{{\boldsymbol {\unicode{x3b1} }}^{(i)}}$
(=the source tableau of
$\mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}}$
) yields that
$\mathbf {w}(\tau _{T^{(i)}_{\alpha }}) \preceq _L \mathbf {w}(\tau _T)$
for
$T \in \mathrm {SRT}(\alpha )^{(i)}$
. Moreover, for each
$m_i \le j < m_{i+1}$
, it holds that
$$ \begin{align} s_j \in \mathrm{Des}_R(\mathbf{w}(\tau_{T^{(i)}_{\alpha}}) s_{m_i} s_{m_i + 1} \cdots s_{j-1})\cap \mathrm{Des}_R(\mathbf{w}(\tau_T) s_{m_i} s_{m_i + 1} \cdots s_{j-1}). \end{align} $$
Here,
$s_{m_i} s_{m_i + 1} \cdots s_{j - 1}$
is regarded as the identity when
$j = m_i$
. Finally, applying Lemma 6.1 to equation (6.2) yields that
$\mathbf {w}(T^{(i)}_{\alpha }) \preceq _L \mathbf {w}(T)$
, as required.
Combining Lemma 6.2 with the equalities
$L(\tau )_i^1 = \tau _i^2$
and
$L(\tau )_{i+1}^1 = \min (\tau _i^1, \tau _{i+1}^1)$
, we derive that
$\partial ^{(i)}_1$
is well-defined.
Lemma 6.3. For
$i \in \mathcal {I}(\alpha )$
,
$\partial _1^{(i)}: \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}} \rightarrow H_n(0) \cdot T^{(i)}_{\alpha }$
is a surjective
$H_n(0)$
-module homomorphism.
Proof. For each
$T \in H_n(0) \cdot T^{(i)}_{\alpha }$
, let
$\tau _T$
be the filling of
$\mathtt {rd}({\boldsymbol {\unicode{x3b1} }}^{(i)})$
defined in equation (6.1). The surjectivity of
$\partial _1^{(i)}$
is straightforward since
$\tau _T \in \mathrm {SRT}({\boldsymbol {\unicode{x3b1} }}^{(i)})$
and
$L(\tau _T)=T$
. Thus, to prove our assertion, it suffices to show that
$$\begin{align*}\partial_1^{(i)}(\pi_k \cdot \tau) = \pi_k \cdot \partial_1^{(i)}(\tau) \end{align*}$$
for all
$k = 1,2, \ldots , n-1$
and
$\tau \in \mathrm {SRT}({\boldsymbol {\unicode{x3b1} }}^{(i)})$
.
Case 1:
$\pi _k \cdot \tau = \tau $
. If
$\partial _1^{(i)}(\tau ) = 0$
, then there is nothing to prove. Suppose that
$\partial _1^{(i)}(\tau ) \neq 0$
: that is,
$L(\tau ) \in \mathrm {SRT}(\alpha )$
. We claim that
$k \notin \mathrm {Des}(L(\tau ))$
. If
$k = \tau _i^1$
and
$k+1 = \tau _i^2$
, then
$k \in L(\tau )_{i+1}^{\bullet }$
and
$k+1 \in L(\tau )_i^{\bullet }$
. If
$k \in \tau _{i+1}^{\bullet }$
and
$k+1 = \tau _i^1$
, then both k and
$k+1$
are in
$L(\tau )_{i+1}^{\bullet }$
. In the remaining cases, from the fact that k is weakly right of
$k+1$
in
$\tau $
, it follows that k is weakly right of
$k+1$
in
$L(\tau )$
. For any cases, we can see that
$k \notin \mathrm {Des}(L(\tau ))$
.
Case 2:
$\pi _k \cdot \tau = 0$
. If
$\partial _1^{(i)}(\tau ) = 0$
, then there is nothing to prove. Suppose that
$\partial _1^{(i)}(\tau ) \neq 0$
. Since k and
$k+1$
are in the same row of
$\tau $
, k is the top and
$k+1$
is the bottom for some two consecutive columns of
$\tau $
. If
$k \neq \tau _i^1$
, then k and
$k+1$
are still in the same row of
$L(\tau )$
, so
$\pi _k \cdot L(\tau ) = \pi _k \cdot \partial _1^{(i)}(\tau ) = 0$
, as required. Assume that
$k = \tau _i^1$
. Note that
$|\tau _i^{\bullet }| = \alpha _i +1 \geq 2$
and
$\tau _i^2$
greater than both k and
$k+1$
. By the definition of
$L(\tau )$
, we have that
$L(\tau )_i^1 = \tau _i^2> L(\tau )_{i+1}^{-1} = k+1$
. This implies that
$\partial _1^{(i)}(\tau )=0$
, which contradicts our assumption
$\partial _1^{(i)}(\tau ) \neq 0$
.
Case 3:
$\pi _k \cdot \tau = s_k \cdot \tau $
. First, consider the case where
$\partial _1^{(i)}(\tau ) = 0$
: that is,
$L(\tau ) \notin \mathrm {SRT}(\alpha )$
. Then
$\tau $
must satisfy either
$\tau _i^2> \tau _{i+1}^{-1}$
or
$\min (\tau _i^1, \tau _{i+1}^1)> \tau _{i+2}^{-1}$
. Thus, to
$L(\pi _k \cdot \tau ) \in \mathrm {SRT}(\alpha )$
, either
$\tau _i^2 = k+1$
and
$\tau _{i+1}^{-1}=k$
or
$\min (\tau _i^1, \tau _{i+1}^1)= k+1$
and
$\tau _{i+2}^{-1}=k$
. However, these are absurd because k is strictly left of
$k+1$
in
$\tau $
.
Next, consider the case where
$\partial _1^{(i)}(\tau ) \neq 0$
: that is,
$L(\tau ) \in \mathrm {SRT}(\alpha )$
. Since
$\pi _k \cdot \tau = s_k \cdot \tau $
, k is strictly left of
$k+1$
in
$\tau $
. Therefore, k is weakly left of
$k+1$
in
$L(\tau )$
by the definition of
$L(\tau )$
. Hence if neither k and
$k+1$
are in the same column in
$L(\tau )$
, nor are they in the same row in
$L(\tau )$
, then
$\pi _k \cdot L(\tau ) = s_k \cdot L(\tau )$
. Therefore, in such case, we have that
$$\begin{align*}\pi_k \cdot \partial_1^{(i)}(\tau) = \pi_k \cdot L(\tau) = s_k \cdot L(\tau) = L(s_k \cdot \tau) = L(\pi_k \cdot \tau)= \partial_1^{(i)}(\pi_k \cdot \tau) . \end{align*}$$
Suppose that k and
$k+1$
are in the same column in
$L(\tau )$
. This is possible only the case where
$k = \tau _i^1$
and
$k+1 \in \tau _{i+1}^{\bullet }$
since k is strictly left of
$k+1$
in
$\tau $
. Moreover,
$k+1 \neq \tau _{i+1}^{-1}$
since
$\pi _k \cdot \tau = s_k \cdot \tau $
. Hence
$k+1 = (\pi _k \cdot \tau )_{i}^1$
and
$k \in (\pi _k \cdot \tau )_{i+1}^{\bullet }$
, which implies that
$L(\tau ) = L(\pi _k \cdot \tau )$
. Therefore, we have
$$\begin{align*}\pi_k \cdot \partial_1^{(i)}(\tau) = \pi_k \cdot L(\tau) = L(\tau) = L(\pi_k \cdot \tau)= \partial_1^{(i)}(\pi_k \cdot \tau) . \end{align*}$$
Here the second equality follows from the assumption that k and
$k+1$
are in the same column in
$L(\tau )$
.
Suppose that k and
$k+1$
are in the same row in
$L(\tau )$
. Then
$\pi _k \cdot L(\tau ) = 0$
. In addition, since
$\pi _k \cdot \tau = s_k \cdot \tau $
, we have that either
$L(\tau _{i+1}^1) = k$
and
$L(\tau )_{i+2}^{-1} = k+1$
, or
$L(\tau )_i^1 = k$
and
$L(\tau )_{i+1}^{-1} = k+1$
. In the case where
$L(\tau )_{i+1}^1 = k$
and
$L(\tau )_{i+2}^{-1} = k+1$
, the assumption
$\pi _k \cdot \tau = s_k \cdot \tau $
implies that
$L(\pi _k \cdot \tau )_{i+1}^1 = k+1$
and
$L(\pi _k \cdot \tau )_{i+2}^{-1} = k$
. Thus,
$L(\pi _k \cdot \tau ) \notin \mathrm {SRT}(\alpha )$
: that is,
$\partial _1^{(i)}(\pi _k \cdot \tau ) = 0$
as desired. In the case where
$L(\tau )_i^1 = k$
and
$L(\tau )_{i+1}^{-1} = k+1$
, one can easily see that
$L(\pi _k \cdot \tau ) \notin \mathrm {SRT}(\alpha )$
. Thus
$\pi _k \cdot \partial _1^{(i)}(\tau ) = 0 = \partial _1^{(i)}(\pi _k \cdot \tau )$
.
Due to Lemma 6.2 and Lemma 6.3, we can view
$\partial _1 = \sum _{i \in \mathcal {I}(\alpha )} \partial _1^{(i)}$
as an
$H_n(0)$
-module homomorphism from
$\bigoplus _{i \in \mathcal {I}(\alpha )} \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}}$
onto
$\Omega (\mathcal {V}_{\alpha })$
. Now, we verify that
$\partial _1$
is an essential epimorphism: that is,
$\ker (\partial _1) \subseteq \mathrm {rad}(\bigoplus _{i \in \mathcal {I}(\alpha )} \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}})$
.
To ease notation, we write
$\boldsymbol {\tau }_{(i)}$
for the source tableau
$\tau _{{\boldsymbol {\unicode{x3b1} }}^{(i)}}$
in
$\mathrm {SRT}({\boldsymbol {\unicode{x3b1} }}^{(i)})$
. When
$i \neq \ell (\alpha )-1$
, we can see that
$$\begin{align*}\begin{aligned} (\boldsymbol{\tau}_{(i)})_{i+1}^q &= m_i+1+q \quad \text{for } 1 \leq q \leq \alpha_{i+1}-1\, \text{, and} \\ (\boldsymbol{\tau}_{(i)})_{i+2}^q &= m_{i+1}+q \quad \text{for } 1 \leq q \leq \alpha_{i+2}\, , \end{aligned} \end{align*}$$
where
$m_i = \sum _{j = 1}^{i}\alpha _j$
. Let
$\hat {\boldsymbol {\tau }}_{(i)}$
denote the
$\mathrm {SRT}$
of shape
${\boldsymbol {\unicode{x3b1} }}^{(i)}$
such that
$$ \begin{align*} \begin{aligned} (\hat{\boldsymbol{\tau}}_{(i)})_{i+1}^q &= m_i+1+ \alpha_{i+2}+q \quad \text{for } 1 \leq q \leq \alpha_{i+1}-1\, , \\ (\hat{\boldsymbol{\tau}}_{(i)})_{i+2}^q &= m_{i}+1+q \quad \text{for } 1 \leq q \leq \alpha_{i+2}\, \text{, and} \\ (\hat{\boldsymbol{\tau}}_{(i)})_p &= (\boldsymbol{\tau}_{(i)})_p \quad \text{for }p \neq i, i+1. \end{aligned} \end{align*} $$
For example, if
$\alpha = (1,3,3,1)$
and
$i = 1$
, then
Observe that
$(\boldsymbol {\tau }_{(i)})^{\bullet }_j = (\hat {\boldsymbol {\tau }}_{(i)})^{\bullet }_j$
for
$j \neq i+1, i+2$
.
Lemma 6.4. For
$i \in \mathcal {I}(\alpha )$
,
$\ker (\partial _1^{(i)}) \subseteq \mathrm {rad}(\mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}} )$
.
Proof. If
$i = \ell (\alpha )-1$
, then
${\boldsymbol {\unicode{x3b1} }}^{(i)}$
is a composition. Therefore,
$\mathrm {rad}(\mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}})$
is the
$\mathbb C$
-span of
$\mathrm {SRT}({\boldsymbol {\unicode{x3b1} }}^{(i)})\setminus \{ \boldsymbol {\tau }_{(i)} \}$
. Since
$\partial _1^{(i)}(\boldsymbol {\tau }_{(i)}) \neq 0$
, this implies that
$\ker (\partial _1^{(i)}) \subseteq \mathrm {rad}(\mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}} )$
.
Suppose that
$i \neq \ell (\alpha )-1$
. Let
$$ \begin{align} \begin{aligned} \beta^{(1)} & = (\alpha_1, \alpha_2, \ldots, \alpha_{i-1}, \alpha_i +1, \alpha_{i+1} - 1, \alpha_{i+2} , \alpha_{i+3}, \ldots, \alpha_{\ell(\alpha)}), \\ \beta^{(2)} & = (\alpha_1, \alpha_2, \ldots, \alpha_{i-1}, \alpha_i +1, \alpha_{i+1} - 1 + \alpha_{i+2} , \alpha_{i+3}, \ldots, \alpha_{\ell(\alpha)}). \end{aligned} \end{align} $$
To ease notation, we denote the source tableaux of
$\mathbf {P}_{\beta ^{(1)}}$
and
$\mathbf {P}_{\beta ^{(2)}}$
by
$\tau ^{(1)}$
and
$\tau ^{(2)}$
, respectively. By Theorem 2.3, we may choose an
$H_n(0)$
-module isomorphism
$$\begin{align*}f:\mathbf{P}_{{\boldsymbol{\unicode{x3b1}}}^{(i)}} \rightarrow \mathbf{P}_{\beta^{(1)}} \oplus \mathbf{P}_{\beta^{(2)}}. \end{align*}$$
Let
$$ \begin{align*}f(\boldsymbol{\tau}_{(i)}) = \sum_{\tau \in \mathrm{SRT}(\beta^{(1)})} c_{\tau} \tau + \sum_{\tau \in \mathrm{SRT}(\beta^{(2)})} d_{\tau} \tau \quad \text{for } c_{\tau}, d_{\tau} \in {\mathbb C}. \end{align*} $$
Since
$f(\boldsymbol {\tau }_{(i)})$
is a generator of
$\mathbf {P}_{\beta ^{(1)}} \oplus \mathbf {P}_{\beta ^{(2)}}$
,
$c_{\tau ^{(1)}}$
and
$d_{\tau ^{(2)}}$
are nonzero.
We claim that
$[\boldsymbol {\tau }_{(i)}, \hat {\boldsymbol {\tau }}_{(i)}]^{\mathrm {c}} \subset \mathrm {rad} (\mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}})$
. Take any
$\tau \notin [\boldsymbol {\tau }_{(i)},\hat {\boldsymbol {\tau }}_{(i)}]$
. To get
$\tau $
from
$\boldsymbol {\tau }_{(i)}$
, there should exist an
$H_n(0)$
-action switching two entries such that at least one of them lies apart from the
$(i+1)$
st and
$(i+2)$
nd columns. Thus there exist
$\sigma , \rho \in \Sigma _n$
and
$k \notin [m_i+2, m_{i+2} - 1]$
such that
$$ \begin{align*}\tau = \pi_{\sigma} \pi_k \pi_{\rho} \cdot \boldsymbol{\tau}_{(i)}, \quad \pi_{\rho} \cdot \boldsymbol{\tau}_{(i)} \in [\boldsymbol{\tau}_{(i)},\hat{\boldsymbol{\tau}}_{(i)}] \quad \text{and} \quad \pi_k \pi_{\rho} \cdot \boldsymbol{\tau}_{(i)} = s_k \cdot (\pi_{\rho} \cdot \boldsymbol{\tau}_{(i)}). \end{align*} $$
Ignoring the columns filled with entries
$[m_i+2, m_{i+2}]$
, we can see that all
$\pi _{\rho } \cdot \boldsymbol {\tau }_{(i)}$
,
$\tau ^{(1)}$
and
$\tau ^{(2)}$
are the same. This implies that
$\pi _k \cdot \tau ^{(j)} = s_k \cdot \tau ^{(j)}$
for
$j = 1,2$
. In all, we have
$$ \begin{align*} f(\tau) &= \pi_{\sigma} \pi_k \pi_{\rho} \cdot f(\boldsymbol{\tau}_{(i)})\\ &= \pi_{\sigma} \pi_k \pi_{\rho} \cdot \left( \sum_{\tau \in \mathrm{SRT}(\beta^{(1)})} c_{\tau} \tau + \sum_{\tau \in \mathrm{SRT}(\beta^{(2)})} d_{\tau} \tau \right) \\ &= \sum_{\substack{\tau \in \mathrm{SRT}(\beta^{(1)}) \\ \tau> \tau^{(1)} }} c^{\prime}_{\tau} \tau + \sum_{\substack{\tau \in \mathrm{SRT}(\beta^{(2)}) \\ \tau > \tau^{(2)} }} d^{\prime}_{\tau} \tau \end{align*} $$
for some
$c^{\prime }_{\tau }, d^{\prime }_{\tau } \in \mathbb C$
. This implies that
$f(\tau ) \in \mathrm {rad}(\mathbf {P}_{\beta ^{(1)}} \oplus \mathbf {P}_{\beta ^{(2)}})$
, and hence
$\tau \in \mathrm {rad}(\mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}})$
.
By virtue of the above discussion, to complete our assertion, it is enough to show that
$\ker (\partial _1^{(i)}) \subseteq \mathbb C [\boldsymbol {\tau }_{(i)}, \hat {\boldsymbol {\tau }}_{(i)}]^{\mathrm {c}}$
, or equivalently,
$L(\tau ) \in \mathrm {SRT}(\alpha )$
for every
$\tau \in [\boldsymbol {\tau }_{(i)},\hat {\boldsymbol {\tau }}_{(i)}]$
. But this is obvious since
$L(\tau )_i^1 = \tau _i^2 = m_{i-1}+2$
,
$L(\tau )_{i+1}^1 = \tau _{i}^{1} = m_{i-1}+1$
and
$L(\tau )_{i+1}^{-1}, L(\tau )_{i+2}^{-1} \in [m_i+2, m_{i+2}]$
.
We are now in place to prove Theorem 3.3.
Proof of Theorem 3.3.
(a) As mentioned after the proof of Lemma 6.3,
$\partial _1: \bigoplus _{i \in \mathcal {I}(\alpha )} \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}} \rightarrow \Omega (\mathcal {V}_{\alpha })$
is a surjective
$H_n(0)$
-module homomorphism. Therefore, we only need to check
$\ker (\partial _1) \subseteq \mathrm {rad} \left (\bigoplus _{i \in \mathcal {I}(\alpha )} \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}} \right )$
to complete the proof of the assertion. Let
$$ \begin{align*}\mathbf{T} := \bigoplus_{i \in \mathcal{I}(\alpha)} \mathbb C[\boldsymbol{\tau}_{(i)},\hat{\boldsymbol{\tau}}_{(i)}] \quad \text{and} \quad \mathbf{B} := \bigoplus_{i \in \mathcal{I}(\alpha)} \mathbb C[\boldsymbol{\tau}_{(i)}, \hat{\boldsymbol{\tau}}_{(i)}]^{\mathrm{c}}. \end{align*} $$
In the proof of Lemma 6.4, we see that
$[\boldsymbol {\tau }_{(i)}, \hat {\boldsymbol {\tau }}_{(i)}]^{\mathrm {c}} \subseteq \mathrm {rad} \, \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}}$
for
$i \in \mathcal {I}(\alpha )$
and thus
$\mathbf {B} \subseteq \mathrm {rad} \left (\bigoplus _{i \in \mathcal {I}(\alpha )} \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}} \right )$
.
In the following, we will prove
$\ker (\partial _1) \subseteq \mathbf {B}$
, which is obviously a stronger inclusion than necessary. We begin by collecting the following properties, which were shown in the proof of Lemma 6.4: For all
$i \in \mathcal {I}(\alpha )$
,
$1\le j < i$
and
$\tau \in [\boldsymbol {\tau }_{(i)},\hat {\boldsymbol {\tau }}_{(i)}]$
,
$$ \begin{align*} &\ker(\partial_1^{(i)}) \subseteq \mathbb C[\boldsymbol{\tau}_{(i)}, \hat{\boldsymbol{\tau}}_{(i)}]^{\mathrm{c}},\\ &\partial_1^{(i)}(\tau)_i^1 = m_{i-1}+2\, \text{ and} \\ &\partial_1^{(i)}(\tau)_j^1 = m_{j-1} +1. \end{align*} $$
Therefore, for any
$i, j \in \mathcal {I}(\alpha )$
with
$j < i$
, if
$\tau \in [\boldsymbol {\tau }_{(i)},\hat {\boldsymbol {\tau }}_{(i)}] \subset \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}}$
and
$\tau ' \in [\boldsymbol {\tau }_{(j)},\hat {\boldsymbol {\tau }}_{(j)}] \subset \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(j)}}$
, then
$\partial _1(\tau )_j^1 = \partial _1^{(i)} (\tau )_j^1 = m_{j-1} + 1$
and
$\partial _1(\tau ')_j^1 = \partial _1^{(j)} (\tau ')_j^1 = m_{j-1} + 2$
: that is,
$\partial _1(\tau ) \neq \partial _1(\tau ')$
. This implies that that the set
$\{\partial _1(\tau ) \mid \tau \in [\boldsymbol {\tau }_{(i)},\hat {\boldsymbol {\tau }}_{(i)}] \text { for } i \in \mathcal {I}(\alpha )\}$
is linearly independent, hence every
$\mathbf {x} \in \ker (\partial _1) \setminus \{0\}$
is decomposed as
$\mathbf {x} = \mathbf {x}^{(1)} + \mathbf {x}^{(2)}$
for some
$\mathbf {x}^{(1)} \in \mathbf {T}$
and
$\mathbf {x}^{(2)} \in \mathbf {B} \setminus \{0\}$
.
We claim that
$\mathbf {x}^{(1)} = 0$
. Suppose on the contrary that
$\mathbf {x}^{(1)} \neq 0$
. Let
$$\begin{align*}\partial_1(\mathbf{x}^{(1)}) = \sum_{T \in \mathrm{SRT}(\alpha) \cap \Omega(\mathcal{V}_{\alpha}) }c_T T \quad \text{and} \quad \partial_1(\mathbf{x}^{(2)}) = \sum_{T \in \mathrm{SRT}(\alpha) \cap \Omega(\mathcal{V}_{\alpha}) }d_T T. \end{align*}$$
Since
$\partial _1(\mathbf {x}^{(1)}) \neq 0$
, there exists
$T \in \mathrm {SRT}(\alpha ) \cap \Omega (\mathcal {V}_{\alpha })$
such that
$c_{T} \neq 0$
. In addition, since
$\mathrm {SRT}(\alpha ) \cap \Omega (\mathcal {V}_{\alpha }) $
is linearly independent and
$\partial _1(\mathbf {x}) = 0$
, we have
$c_{T} = -d_{T}$
. Therefore, there exist
$i,j \in \mathcal {I}(\alpha )$
,
$\tau _{\mathbf {T}} \in [\boldsymbol {\tau }_{(i)}, \hat {\boldsymbol {\tau }}_{(i)}]$
and
$\tau _{\mathbf {B}} \in [\boldsymbol {\tau }_{(j)}, \hat {\boldsymbol {\tau }}_{(j)}]^{\mathrm {c}}$
such that
$\partial _1(\tau _{\mathbf {T}}) = T = \partial _1(\tau _{\mathbf {B}})$
. Since
$\{\partial _1(\tau ) \mid \tau \in \mathrm {SRT}({\boldsymbol {\unicode{x3b1} }}^{(i)})\} \setminus \{0\}$
is linearly independent, we have
$i \neq j$
. Note that
$\partial _1(\tau _{\mathbf {B}}) = \partial _1^{(j)}(\tau _{\mathbf {B}}) \in H_n(0)\cdot T^{(j)}_{\alpha }$
. By Lemma 6.2, we have
$T_j^1> T_{j+1}^1$
. On the other hand, since
$T = \partial _1^{(i)}(\tau _{\mathbf {T}})$
and
$\tau _{\mathbf {T}} \in [\boldsymbol {\tau }_{(i)}, \hat {\boldsymbol {\tau }}_{(i)}]$
, T is equal to
$T^{(i)}_{\alpha }$
except for the
$(i+1)$
st and
$(i+2)$
nd columns. Note that the
$(i+1)$
st and
$(i+2)$
nd columns of them are filled with
$\{ (\tau _{\mathbf {T}})_i^1 \} \cup [m_i+2, m_{i+2}]$
and
$T_{i+1}^1 = \partial _1^{(i)}(\tau _{\mathbf {T}})_{i+1}^1 = m_{i-1} + 1$
. This shows that
$T_j^1 < T_{j+1}^1$
, which is absurd. Hence
$\mathbf {x}^{(1)} = 0$
, and it follows that
$\ker (\partial _1) \subseteq \mathbf {B}$
, as required.
(b) For all
$\beta \models n$
, it is known that
$$\begin{align*}\mathrm{Ext}_{H_n(0)}^1(\mathcal{V}_{\alpha},\mathbf{F}_{\beta})=\mathrm{Hom}_{H_n(0)}(P_1,\mathbf{F}_{\beta}) \end{align*}$$
with
$P_1:=\displaystyle { \bigoplus _{i \in \mathcal {I}(\alpha )} \mathbf {P}_{{\boldsymbol {\unicode{x3b1} }}^{(i)}}}$
(for instance, see [Reference Benson3, Corollary 2.5.4]). In the case with projective indecomposable modules, one has that
$\dim \mathrm {Hom}_{H_n(0)}(\mathbf {P}_{\gamma },\mathbf {F}_{\gamma '})=\delta _{\gamma ,\gamma '}$
for all
$\gamma , \gamma ' \models n$
(see [Reference Benson3, Lemma 1.7.5]). This tells us that
$\dim \mathrm {Ext}_{H_n(0)}^1(\mathcal {V}_{\alpha },\mathbf {F}_{\beta })$
counts the multiplicity of
$\mathbf {P}_{\beta }$
in the decomposition of
$P_1$
into indecomposables. The indecomposables that occur in the decomposition are precisely
$\mathbf {P}_{\beta }$
with
$\beta \in \mathcal {J}(\alpha )$
. We claim that all of them are multiplicity-free. For
$i \in \mathcal {I}(\alpha )$
, note that
$[{\boldsymbol {\unicode{x3b1} }}^{(i)}]=\{\beta ^{(1)}, \beta ^{(2)}\}$
with
$\beta ^{(1)}, \beta ^{(2)}$
in equation (6.3). Obviously
$\beta ^{(1)}$
and
$\beta ^{(2)}$
are distinct. Furthermore, for
$i<j$
,
$[{\boldsymbol {\unicode{x3b1} }}^{(i)}]$
and
$[{\boldsymbol {\unicode{x3b1} }}^{(j)}]$
are disjoint since the ith entry of the compositions in the former is
$\alpha _i+1$
, whereas that of the compositions in the latter is
$\alpha _i$
. Hence the claim is verified, which completes the proof.
6.2 Proof of Theorem 4.1
We begin by introducing the necessary terminologies, notations and lemmas. First, we recall the notation related to parabolic subgroups of
$\Sigma _n$
. For each subset I of
$[n-1]$
, we write
$(\Sigma _n)_I$
for the parabolic subgroup of
$\Sigma _n$
generated by simple transpositions
$s_i$
with
$i\in I$
and
$w_0(I)$
for the longest element of
$(\Sigma _n)_I$
. When I is a subinterval
$[k_1,k_2]$
of
$[n-1]$
and
$c \in I$
, we write
$(\Sigma _n)_I^{(c)}$
for
$$ \begin{align*} \left\{ \sigma \in (\Sigma_{n})_I \, \middle| \, \genfrac{}{}{0pt}{}{ \ \sigma(k_1) < \sigma(k_1 + 1) < \cdots < \sigma(c) \text{ and} }{\sigma(c + 1) < \sigma(c + 2) < \cdots < \sigma(k_2+1)} \right\} \end{align*} $$
and
$w_0(I;c)$
for the longest element of
$(\Sigma _n)_I^{(c)}$
(see [Reference Björner and Brenti8, Chapter 2]).
Next, we introduce the sink tableau of
$\mathbf {P}_{\boldsymbol {\unicode{x3b1} }}$
. Given a generalised composition
${\boldsymbol {\unicode{x3b1} }}$
of n,
$\mathbf {P}_{\boldsymbol {\unicode{x3b1} }}$
contains a unique tableau T such that
$\pi _i \cdot T = 0$
or T for all
$i \in [n-1]$
. We call it the sink tableau of
$\mathbf {P}_{\boldsymbol {\unicode{x3b1} }}$
, denoted by
$T^{\leftarrow }_{\boldsymbol {\unicode{x3b1} }}$
. Explicitly,
$T^{\leftarrow }_{\boldsymbol {\unicode{x3b1} }}$
is obtained by filling in
$\mathtt {rd}({\boldsymbol {\unicode{x3b1} }})$
with entries
$1, 2, \ldots , n$
from left to right and from top to bottom. Let us define a bijection
$$\begin{align*}\chi_{\boldsymbol{\unicode{x3b1}}}: \mathrm{SRT}({\boldsymbol{\unicode{x3b1}}}) \rightarrow \bigcup_{\beta \in [{\boldsymbol{\unicode{x3b1}}}]} \mathrm{SRT}(\beta), \quad T \mapsto T', \end{align*}$$
where
$T'$
is uniquely determined by the condition
$\mathbf {w}(T) = \mathbf {w}(T')$
. With this bijection, we define
$$ \begin{align*} {T^{\leftarrow}_{\beta;{\boldsymbol{\unicode{x3b1}}}}} := \chi_{\boldsymbol{\unicode{x3b1}}}^{-1}(T^{\leftarrow}_{\beta}) \quad \text{ for every } \beta \in [{\boldsymbol{\unicode{x3b1}}}]. \end{align*} $$
For
$\beta \in [\underline {{\boldsymbol {\unicode{x3b1} }}}]$
, we let
$$ \begin{align*}\mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}}:= \{i \in [n-1] \mid \pi_i \cdot T^{\leftarrow}_{\beta} = 0, \text{ but } \pi_i \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}}} \neq 0 \}. \end{align*} $$
For each
$1 \le i \le n-1$
, let
$\overline {\pi }_i := \pi _i -1$
. Pick up any reduced expression
$s_{i_1}\cdots s_{i_p}$
for
$\sigma \in \Sigma _n$
. Let
$\overline {\pi }_{\sigma }$
be the element of
$H_n(0)$
defined by
$\overline {\pi }_{\sigma } := \overline {\pi }_{i_1} \cdots \overline {\pi }_{i_p}$
. It is well known that the element
$\overline {\pi }_{\sigma }$
is independent of the choice of reduced expressions.
Lemma 6.5 [Reference Jung, Kim, Lee and Oh21, Lemma 3 (1)].
For any
$\sigma , \rho \in \Sigma _n$
,
$\pi _{\sigma } \overline {\pi }_{\rho }$
is nonzero if and only if
$\ell (\sigma \rho ) = \ell (\sigma ) + \ell (\rho )$
.
The following lemma gives an explicit description for
$\mathrm {soc}(\mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}})$
.
Lemma 6.6. For
$\beta \in [\underline {{\boldsymbol {\unicode{x3b1} }}}]$
,
$\mathbb C T^{\leftarrow }_{\beta }$
is isomorphic to
$\mathbb C\left ( \overline {\pi }_{w_0(\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}})} \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}}\right )$
as an
$H_n(0)$
-module.
Proof. First, we claim that
$\overline {\pi }_{w_0(\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}})} \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}}$
is stabilised under the action of
$\pi _i$
for all
$i \in \mathrm {Des}(T_{\beta }^{\leftarrow })^{\mathrm {c}}$
. Note that
$\overline {\pi }_{w_0(\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}})} \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}}$
is of the form
$$ \begin{align} \sum_{T \in [{T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}}}, T_{\underline{{\boldsymbol{\unicode{x3b1}}}}}^{\leftarrow}]} c_T T \quad \text{for some } c_T \in {\mathbb Z}. \end{align} $$
But from the definitions of
${T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}}$
and
$T_{\underline {{\boldsymbol {\unicode{x3b1} }}}}^{\leftarrow }$
, it follows that
$\pi _i \cdot T = T$
for
$i \in \mathrm {Des}(T_{\beta }^{\leftarrow })^{\mathrm {c}}$
. Thus our claim is verified.
Next, we claim that
$\pi _i \cdot (\overline {\pi }_{w_0(\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}})} \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}}) = 0$
for all
$i \in \mathrm {Des}(T_{\beta }^{\leftarrow })$
. Take any
$i \in \mathrm {Des}(T_{\beta }^{\leftarrow })$
. Note that
$T(\mathtt {S}_{k_0}) = \{1,2,\ldots ,\ell (\alpha )\}$
for any
$T \in [{T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}}, T_{\underline {{\boldsymbol {\unicode{x3b1} }}}}^{\leftarrow }]$
. Therefore, if
$1 \leq i < \ell (\alpha )$
, then
$\pi _i \overline {\pi }_{w_0(\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}})} \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}} = 0$
by equation (6.4). In the case where
$i \ge \ell (\alpha )$
,
$i \in \mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}$
and thus
$\pi _i \overline {\pi }_{w_0(\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}})}= 0$
by Lemma 6.5.
Example 6.7. Given
$\alpha = (2^3)$
, let
$\beta = (1^2,2,1^2)$
and
$\gamma = (2^2,1^2)$
be compositions in
$[\underline {{\boldsymbol {\unicode{x3b1} }}}] = [(1) \oplus (1) \oplus (2,1^2)]$
. Note that
Since
$\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}} = \{4,5\}$
and
$\mathtt {J}_{\gamma ;\underline {{\boldsymbol {\unicode{x3b1} }}}} = \{4\}$
, it follows that
$w_0(\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}) = s_4 s_5 s_4$
and
$w_0(\mathtt {J}_{\gamma ;\underline {{\boldsymbol {\unicode{x3b1} }}}}) = s_4 $
. Thus we have
Proof of Theorem 4.1.
We first claim that
$\epsilon : \mathcal {V}_{\alpha } \to \mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}}$
is an
$H_n(0)$
-module homomorphism: that is,
$$ \begin{align*} \epsilon(\pi_i \cdot \mathscr{T}) = \pi_i \cdot \epsilon(\mathscr{T}) \quad\text{ for } i=1,2,\ldots,n-1 \text{ and }\mathscr{T} \in \mathrm{SIT}(\alpha). \end{align*} $$
Let us fix
$1 \le i \le n-1$
and
$\mathscr {T} \in \mathrm {SIT}(\alpha )$
. Let
$0 \leq x, y \leq m$
be integers satisfying that
$i \in \mathscr {T}(\mathtt {S}_{k_x})$
and
$i+1 \in \mathscr {T}(\mathtt {S}_{k_y})$
.
Case 1:
$\pi _i \cdot \mathscr {T} = \mathscr {T}$
. First we handle the case where
$x=0$
. Then i will be placed in the top row in
${T^{\mathscr {T}}}$
. In view of the given condition
$\pi _i \cdot \mathscr {T} = \mathscr {T}$
, one sees that
$x \neq y$
. This implies that
$i+1$
is strictly below i in
${T^{\mathscr {T}}}$
. Next we handle the case where
$x>0$
. The condition
$\pi _i \cdot \mathscr {T} = \mathscr {T}$
says that
$0 < x \leq y$
; thus
$i+1$
is strictly below i in
${T^{\mathscr {T}}}$
. In either case, it is immediate from equation (2.1) that
$\pi _i \cdot {T^{\mathscr {T}}} = {T^{\mathscr {T}}}$
.
Case 2:
$\pi _i \cdot \mathscr {T} = 0$
. From equation (2.2), it follows that i and
$i+1$
are in the first column in
$\mathscr {T}$
: that is,
$x = y = 0$
. Hence, in
${T^{\mathscr {T}}}$
, both of them will appear in
${T^{\mathscr {T}}}(\mathtt {S}_{k_0})$
. As in Case 1, one can derive from equation (2.1) that
$\pi _i \cdot {T^{\mathscr {T}}} = 0$
.
Case 3:
$\pi _i \cdot \mathscr {T} = s_i \cdot \mathscr {T}$
. We claim that
$\epsilon (s_i \cdot \mathscr {T}) = s_i \cdot {T^{\mathscr {T}}}$
. Observe that i appears strictly above
$i+1$
in
$\mathscr {T}$
. If
$i+1 \in \mathscr {T}(\mathtt {S}_{k_0})$
, then we see that
$i \notin \mathscr {T}(\mathtt {S}_{k_0})$
, which means i appears strictly left of
$i+1$
in
${T^{\mathscr {T}}}$
. Otherwise, we also see that
$i \notin \mathscr {T}(\mathtt {S}_{k_0})$
. More precisely, if
$i+1 \notin \mathscr {T}(\mathtt {S}_{k_0})$
and
$i \in \mathscr {T}(\mathtt {S}_{k_0})$
, then
$\mathscr {T}$
is not an SIT since the entries in the row containing
$i+1$
of
$\mathscr {T}$
do not increase from left to right. It follows from the construction of
${T^{\mathscr {T}}}$
that i is strictly below
$i+1$
in
${T^{\mathscr {T}}}$
. In either case, it holds that
$T^{s_i \cdot \mathscr {T}} = s_i \cdot {T^{\mathscr {T}}}$
. Thus we conclude that
$$ \begin{align*}\pi_i \cdot \epsilon(\mathscr{T}) = \pi_i \cdot {T^{\mathscr{T}}} = T^{s_i \cdot \mathscr{T}} = \epsilon(s_i \cdot \mathscr{T}) = \epsilon(\pi_i \cdot \mathscr{T}). \end{align*} $$
We next claim that
$\mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}}$
is an essential extension of
$\epsilon (\mathcal {V}_{\alpha })$
. To do this, we see that
$\mathrm {soc}(\mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}}) \subset \epsilon (\mathcal {V}_{\alpha })$
. Note that
$$ \begin{align*} \mathrm{soc}(\mathbf{P}_{\underline{{\boldsymbol{\unicode{x3b1}}}}}) \cong \mathrm{soc} \Big(\bigoplus_{\beta \in [\underline{{\boldsymbol{\unicode{x3b1}}}}]} \mathbf{P}_{\beta} \Big) \cong \bigoplus_{\beta \in [\underline{{\boldsymbol{\unicode{x3b1}}}}]} \mathbb C T^{\leftarrow}_{\beta}. \end{align*} $$
In view of Lemma 6.6, one sees that
$$ \begin{align} \mathrm{soc}(\mathbf{P}_{\underline{{\boldsymbol{\unicode{x3b1}}}}}) = \bigoplus_{\beta \in [\underline{{\boldsymbol{\unicode{x3b1}}}}]} \mathbb C\left( \overline{\pi}_{w_0(\mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}})} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}}}\right). \end{align} $$
Choose any
$\beta \in [\underline {{\boldsymbol {\unicode{x3b1} }}}]$
. Then
$$ \begin{align*} \overline{\pi}_{w_0(\mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}})} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}}} = \sum_{\sigma \in (\Sigma_n)_{\mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}}}} (-1)^{\ell(w_0(\mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}})) - \ell(\sigma)} \pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}}}. \end{align*} $$
For
$\sigma \in (\Sigma _n)_{\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}}$
, since
$(\pi _{\sigma } \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}})(\mathtt {S}_{k_0}) = \{1,2, \ldots , \ell (\alpha )\}$
, we have
$$ \begin{align*} (\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}}})^1_{m+k_j-1} < \begin{cases} (\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}}})^{1}_j & \text{if } 1 \leq j < m, \\[1ex] (\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}}})^{2}_j & \text{if } j = m. \end{cases} \end{align*} $$
It means
$\pi _{\sigma } \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}} \in \epsilon (\mathcal {V}_{\alpha })$
for all
$\sigma \in (\Sigma _n)_{\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}}}$
. Combining this with equation (6.5) yields that
$\mathrm {soc}(\mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}}) \subset \epsilon (\mathcal {V}_{\alpha })$
.
6.3 Proof of Theorem 4.3
Throughout this section, let us fix an integer
$1 \le j \le m$
unless otherwise stated.
Let
$T \in \mathrm {SRT}(\underline {{\boldsymbol {\unicode{x3b1} }}})$
. In the same notation as in Section 4, we claim that
$$ \begin{align} {\boldsymbol{\tau}}_{T;j} \neq 0 \quad \text{if and only if} \quad T^{1+\delta_{j,m}}_j < T^1_{m+k_j-1}. \end{align} $$
This is because if
$T^{1+\delta _{j,m}}_j < T^1_{m+k_j-1}$
, then
$\textsf {end}(\mathbf {w}_{T;j}) < T^1_{m+k_j-1}$
and therefore
${\boldsymbol {\tau }}_{T;j} \neq 0$
. Otherwise,
${\boldsymbol {\tau }}_{T;j}$
should be zero since
$\textsf {end}(\mathbf {w}_{T;j})> T^1_{m+k_j-1}$
.
Let
$\beta \in [\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}]$
. Recall that
${T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}} = \chi _{\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}^{-1}(T^{\leftarrow }_{\beta })$
and
$$ \begin{align*} \mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}= \{i \in [n-1] \mid \pi_i \cdot T^{\leftarrow}_{\beta} = 0, \text{ but } \pi_i \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}} \neq 0 \}. \end{align*} $$
Note that if
$\min (\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}) \leq \ell (\alpha )$
, then
$$ \begin{align} \min(\mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}) = |\mathtt{S}^{\prime}_{k_0}| \quad \text{and} \quad \min\left(\mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}} \setminus \{|\mathtt{S}^{\prime}_{k_0}|\} \right)> \ell(\alpha) + 1. \end{align} $$
Set
$$ \begin{align*}\widehat{\mathtt{J}}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}:= \begin{cases} \mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}} \setminus \{|\mathtt{S}^{\prime}_{k_0}|\} & \text{if } 1 \leq \min(\mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}) \leq \ell(\alpha), \\ \mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}} & \text{otherwise,} \end{cases} \end{align*} $$
and
$$ \begin{align*}\boldsymbol{w_0}(\beta;j):= \begin{cases} w_0([\ell(\alpha)];|\mathtt{S}^{\prime}_{k_0}|) \cdot w_0(\widehat{\mathtt{J}}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}) & \text{if } 1 \leq \min(\mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}) \leq \ell(\alpha), \\ w_0(\mathtt{J}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}) & \text{otherwise.} \end{cases} \end{align*} $$
In view of equation (6.7), we know that every element of
$(\Sigma _{n})_{[\ell (\alpha )]}^{(|\mathtt {S}^{\prime }_{k_0}|)}$
commutes with that of
$(\Sigma _n)_{\widehat {\mathtt { J}}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}}$
. The following lemma is necessary to show that
$\mathrm {soc}(\bigoplus _{1 \leq j \leq m}\mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}) \subseteq \mathrm {Im}(\overline {\partial ^1})$
.
Lemma 6.8. For
$1 \leq j \leq m$
and
$\beta \in [\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}]$
,
$\mathbb C T^{\leftarrow }_{\beta } \cong \mathbb C (\overline {\pi }_{\boldsymbol {w_0}(\beta ;j)} \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}})$
as
$H_n(0)$
-modules.
Proof. Let
$1 \leq j \leq m$
and
$\beta \in [\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}]$
. If
$\min (\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}})> \ell (\alpha )$
, then one can prove the assertion in the same way as in Lemma 6.6. We now assume that
$\min (\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}) \leq \ell (\alpha )$
. We first show that
$$ \begin{align*} \pi_i \cdot (\overline{\pi}_{\boldsymbol{w_0}(\beta;j)} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}) = \overline{\pi}_{\boldsymbol{w_0}(\beta;j)} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}} \end{align*} $$
for
$i \notin \mathrm {Des}(T^{\leftarrow }_{\beta })$
. Since
$$ \begin{align*} \overline{\pi}_{\boldsymbol{w_0}(\beta;j)} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}} = \sum_{T \in [{T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}, T_{\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}^{\leftarrow}]} c_T T \quad \text{for some } c_T \in \mathbb Z, \end{align*} $$
it suffices to show that
$\pi _i \cdot T = T$
for
$i \notin \mathrm {Des}(T_{\beta }^{\leftarrow })$
and
$T \in [{T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}}, T_{\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}^{\leftarrow }]$
. Since
$\{1,2,\ldots , \ell (\alpha )\}\subseteq \mathrm {Des}(T^{\leftarrow }_{\beta })$
by definition, we only consider that
$i \geq \ell (\alpha )+1$
. If
$i=\ell (\alpha )+1$
, then the assertion follows from the fact that
$T(\mathtt {S}^{\prime }_{k_0})\cup T(\mathtt {S}^{\prime }_{k_{-1}}) = \{1,2,\ldots ,\ell (\alpha )+1\}$
. Otherwise, from the definitions of
${T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}}$
and
$T_{\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}^{\leftarrow }$
, it follows that
$\pi _i \cdot T = T$
for
$i \notin \mathrm {Des}(T_{\beta }^{\leftarrow })$
. Thus our claim is verified.
We next show that
$\pi _i \cdot (\overline {\pi }_{\boldsymbol {w_0}(\beta ;j)} \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}}) = 0$
for
$i \in \mathrm {Des}(T^{\leftarrow }_{\beta })$
. Take any
$i \in \mathrm {Des}(T_{\beta }^{\leftarrow })$
. If
$i> \ell (\alpha ) + 1$
, then
$i \in \widehat {\mathtt {J}}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}$
. Therefore, by Lemma 6.5, we have
$\pi _i \overline {\pi }_{\boldsymbol {w_0}(\beta ;j)} = 0$
, which implies
$\pi _i \overline {\pi }_{\boldsymbol {w_0}(\beta ;j)} \cdot T^{\leftarrow }_{\beta ,\underline {{\boldsymbol {\unicode{x3b1} }}}} = 0$
. Suppose that
$i \le \ell (\alpha ) + 1$
. Since
$\ell (\alpha ) + 1 \notin \mathrm {Des}(T^{\leftarrow }_{\beta })$
, we have that
$1 \le i \le \ell (\alpha )$
. If
$i \in \mathrm {Des}_L(\boldsymbol {w_0}(\beta ;j))$
, then
$\pi _i \overline {\pi }_{\boldsymbol {w_0}(\beta ;j)} = 0$
. Thus,
$\pi _i \overline {\pi }_{\boldsymbol {w_0}(\beta ;j)} \cdot T^{\leftarrow }_{\beta ,\underline {{\boldsymbol {\unicode{x3b1} }}}} = 0$
. Otherwise, we have
$s_i w_0([\ell (\alpha )];|\mathtt {S}^{\prime }_{k_0}|) = \sigma s_{i'}$
for some
$\sigma \in (\Sigma _{n})_{[\ell (\alpha )]}^{(|\mathtt {S}^{\prime }_{k_0}|)}$
and
$1\le i' \le \ell (\alpha )$
with
$i' \neq |\mathtt {S}^{\prime }_{k_0}|$
since
$w_0([\ell (\alpha )];|\mathtt {S}^{\prime }_{k_0}|)$
is the unique longest element in
$(\Sigma _{n})_{[\ell (\alpha )]}^{(|\mathtt {S}^{\prime }_{k_0}|)}$
. Combining this with [Reference Jung, Kim, Lee and Oh21, Lemma 1], we have that
$\pi _i \overline {\pi }_{\boldsymbol {w_0}(\beta ;j)} = \mathbf {h} \pi _{i'}$
for some
$\mathbf {h} \in H_n(0)$
and
$1 \le i' \le \ell (\alpha )$
with
$i' \neq |\mathtt {S}^{\prime }_{k_0}|$
. Since
$\pi _{i'} \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}} = 0$
for all
$1 \le i' \le \ell (\alpha )$
with
$i' \neq |\mathtt {S}^{\prime }_{k_0}|$
, it follows that
$$ \begin{align*} \pi_i \cdot (\overline{\pi}_{\boldsymbol{w_0}(\beta;j)} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}) = \mathbf{h} \pi_{i'} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}} = 0.\\[-3.4pc] \end{align*} $$
Example 6.9. Let
$\alpha = (2,1,2,3) \models 8$
. Note that
$\mathcal {K}(\alpha ) = \{0,1,3,4\}$
and
$\ell (\alpha )=4$
. Then
$\underline {{\boldsymbol {\unicode{x3b1} }}}_{(2)} = (1) \oplus (3,1^2) \oplus (1^2)$
. Let
$\beta = (1,3,1^4)$
and
$\gamma = (1,3,1,2,1)$
in
$[\underline {{\boldsymbol {\unicode{x3b1} }}}_{(2)}]$
. Note that
Here the entries i in red in each SRT T are being used to indicate that
$\pi _i \cdot T = 0$
. Since
$\min (\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(2)}}) = 3 \le \ell (\alpha )$
and
$ \min (\mathtt {J}_{\gamma ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(2)}}) = 7> \ell (\alpha )$
,
$$\begin{align*}\boldsymbol{w_0}(\beta;2) = s_2 s_3 s_4 s_1 s_2 s_3 \cdot s_7 \qquad\text{and}\qquad \boldsymbol{w_0}(\gamma;2) = s_7. \end{align*}$$
Therefore, by Lemma 6.8, we have
From now on, suppose that
$n \ge 3$
. Fix
$l \in [2, n-1]$
and
$c \in [2,l]$
. For
$\omega \in \left (\Sigma _{n}\right )_{[l]}^{(c)}$
, let
$\Delta (\omega )$
be the permutation in
$\left (\Sigma _{n}\right )_{[l]}^{(c)}$
such that
$\Delta (\omega )(i)=\omega (1) + i-1$
for
$1\le i \le c$
. Then we consider the map
$$ \begin{align*} \phi: \left(\Sigma_{n}\right)_{[l]}^{(c)}\rightarrow (\Sigma_n)_{[l]}, \quad \omega \mapsto \omega \Delta(\omega)^{-1}. \end{align*} $$
It can be easily seen that
$$ \begin{align} \begin{aligned} &\bullet\, \phi(\omega)(i) = i \text{ for } 1 \leq i \leq \omega(1), \\ &\bullet\, \phi(\omega)(\omega(1)+1) <\phi(\omega)(\omega(1)+2) < \cdots <\phi(\omega)(\omega(1)+c-1),\\ &\bullet\,\phi(\omega)(\omega(1)+c) <\phi(\omega)(\omega(1)+c+1) < \cdots <\phi(\omega)(l+1) \end{aligned} \end{align} $$
and particularly
$\phi $
is an injective map. Note that
$\omega (1)$
can have values belonging to
$[l-c+2]$
. For
$1 \leq u \leq l-c+2$
, equation (6.8) implies that
$$ \begin{align*} \phi\left(\{\omega\in \left(\Sigma_{n}\right)_{[l]}^{(c)}: \omega(1)=u\}\right) = (\Sigma_n)^{(c+u-1)}_{[u+1,l]}. \end{align*} $$
Here
$(\Sigma _n)^{(l+1)}_{[u + 1, l]}$
is set to be
$\{\mathrm {id}\}$
. Hence, letting
$\Delta _u$
be the permutation in
$\left (\Sigma _{n}\right )_{[l]}^{(c)}$
such that
$\Delta _u(i) = u+i-1$
for
$1 \leq i \leq c$
, we have the following decomposition:
$$ \begin{align} \left(\Sigma_{n}\right)_{[l]}^{(c)} = \bigsqcup_{1 \le u \le l - c + 2} \left\{\zeta \Delta_u \mid \zeta \in (\Sigma_n)^{(c + u - 1)}_{[u + 1, l]} \right\}. \end{align} $$
In the following, for each
$\omega \in \left (\Sigma _{n}\right )_{[l]}^{(c)}$
, we will show that
$\pi _{\omega } = \pi _{\phi (\omega )} \pi _{\Delta (\omega )}$
. Note that
$$ \begin{align} \ell(\Delta(\omega)) = c(\omega(1)-1) \quad \text{and} \quad \ell(\omega) = \sum_{1 \leq i \leq c} (\omega(i)-i). \end{align} $$
Since
$\phi (\omega ) \in (\Sigma _n)_{[\omega (1) + 1, l]}^{(c + \omega (1) - 1)}$
,
$$\begin{align*}\ell(\phi(\omega)) = \sum_{\omega(1) + 1 \le i \le \omega(1) + c - 1} \left( \phi(\omega)(i) - i \right) = \sum_{1 \le i \le c -1} \left( \phi(\omega)(\omega(1) + i) - \omega(1) - i \right). \end{align*}$$
From the construction of
$\phi $
, one sees that
$\phi (\omega )(\omega (1) + i) = \omega (i + 1)$
, and thus
$$\begin{align*}\ell(\phi(\omega)) = \sum_{1 \le i \le c -1} \left( \omega(i + 1) - \omega(1) - i \right). \end{align*}$$
Combining this equality with equation (6.10) yields that
$$ \begin{align*} \ell(\phi(\omega)) + \ell(\Delta(\omega)) & = \sum_{1 \le i \le c -1} \left( \omega(i + 1) - \omega(1) - i \right) + c(\omega(1)-1) \\ & = \sum_{1 \leq i \leq c} (\omega(i)-i) = \ell(\omega). \end{align*} $$
Since
$\omega = \phi (\omega ) \Delta (\omega )$
, we have that
$\Delta (\omega ) \preceq _L \omega $
, and thus
$$ \begin{align} \pi_{\omega} = \pi_{\phi(\omega)} \pi_{\Delta(\omega)}. \end{align} $$
Let
$1 \le j \le m$
and
$\beta \in [\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}]$
. For
$\sigma \preceq _L \boldsymbol {w_0}(\beta ;j)$
, we define
$T_{j;\beta }(\sigma )$
to be the filling of
$\mathtt {rd}(\underline {{\boldsymbol {\unicode{x3b1} }}})$
such that the column strip
$\mathtt {S}_{k_r}$
(
$1 \leq r \leq m$
) is filled with the entries of
$$ \begin{align*}\begin{cases} (\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}})(\mathtt{S}^{\prime}_{k_j}) \cup \{\min((\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}})(\mathtt{S}^{\prime}_{k_0}))\} & \text{ if } r = j,\\ (\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}})(\mathtt{S}^{\prime}_{k_r}) & \text{ otherwise } \end{cases} \end{align*} $$
in such a way that the entries increase from top to bottom and the row strip
$\mathtt {S}_{k_0}$
is filled with the entries of
$$ \begin{align*}\left( (\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}})(\mathtt{S}^{\prime}_{k_{-1}}) \cup (\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}})(\mathtt{S}^{\prime}_{k_{0}}) \right) \setminus \{\min((\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}})(\mathtt{S}^{\prime}_{k_0}))\} \end{align*} $$
in such a way that the entries increase from left to right.
Example 6.10. Let us revisit Example 6.9. Recall
$\beta =(1,3,1^4)$
and
$\underline {{\boldsymbol {\unicode{x3b1} }}}_{(2)} =(1) \oplus (3,1^2) \oplus (1^2)$
. For
$\sigma = s_{[1,3]}, s_4s_{[1,3]}$
and
$s_{[3,4]}s_{[1,3]}$
, it holds that
$\sigma \preceq _L \boldsymbol {w_0}(\beta ;2)$
and
Using these, we can check that
for all
$\sigma = s_{[1,3]}, s_4s_{[1,3]},s_3s_4s_{[1,3]}$
.
If there is no confusion for j and
$\beta $
, then we simply write
$T(\sigma )$
for
$T_{j;\beta }(\sigma )$
. For
$\Theta (\mathcal {V}_{\alpha })$
defined in equation (4.1), we have the following lemma.
Lemma 6.11. Suppose we have a pair
$(j,\beta )$
with
$1 \le j \le m$
and
$\beta \in [\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}]$
satisfying that
$\min (\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}) \leq \ell (\alpha )$
. Then for every permutation
$\sigma \in \Sigma _n$
with
$\sigma \preceq _L \boldsymbol {w_0}(\beta ;j)$
, it holds that
$T(\sigma ) \in \Theta (\mathcal {V}_{\alpha })$
.
Proof. It is clear that
$T(\sigma ) \in \mathrm {SRT}(\underline {{\boldsymbol {\unicode{x3b1} }}})$
. Thus, for the assertion, we have only to show that
$T(\sigma )_j^{1+\delta _{j,m}} < T(\sigma )^1_{m+k_j-1}$
. Note that
$$ \begin{align*} (\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}) (\mathtt{S}^{\prime}_{k_{-1}}) \cup (\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}) (\mathtt{S}^{\prime}_{k_0}) = \{1,2,\ldots,\ell(\alpha)+1\}, \end{align*} $$
which implies that
$$\begin{align*}1 \leq \min((\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}) (\mathtt{S}^{\prime}_{k_0})) \leq |\mathtt{S}^{\prime}_{k_{-1}}|+1. \end{align*}$$
Since
$|\mathtt {S}^{\prime }_{k_{-1}}| = k_j-1$
, it follows that
$\min ((\pi _{\sigma } \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}})(\mathtt {S}^{\prime }_{k_0})) \leq k_j$
. On the other hand, from the observation that
$T(\sigma )^1_{m+k_j-1}$
is the
$k_j$
th smallest element in the set
$$\begin{align*}\{1,2,\ldots,\ell(\alpha)+1\}\setminus\{\min(\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}(\mathtt{S}^{\prime}_{k_0}))\}, \end{align*}$$
we see that
$k_j < T(\sigma )^1_{m+k_j-1}$
. As a consequence, we derive the following inequality:
$$ \begin{align*} T(\sigma)^{1+\delta_{j,m}}_j = \min((\pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}})(\mathtt{S}^{\prime}_{k_0})) \leq k_j < T(\sigma)^1_{m+k_j-1}.\\[-3.3pc] \end{align*} $$
We are now ready to prove Theorem 4.3.
Proof of Theorem 4.3.
(a) Given
$1 \le i \le n-1$
and
$T \in \mathrm {SRT}(\underline {{\boldsymbol {\unicode{x3b1} }}})$
, we have three cases.
Case 1:
$\pi _i \cdot T = T$
. We claim that
$i \notin \mathrm {Des}(\tau _{T;j;A})$
for all
$1 \leq j \leq m$
and
$A \in \mathcal {P}(\mathtt {A}_{T;j})$
. Fix
$j \in [m]$
and
$A \in \mathcal {P}(\mathtt {A}_{T;j})$
. Since
$i \notin \mathrm {Des}(T)$
, i is weakly right of
$i+1$
in T. If neither i nor
$i+1$
appears in
$\mathbf {w}_{T;j}$
, then i and
$i+1$
still hold their positions in
$\tau _{T;j;A}$
, so
$i \notin \mathrm {Des}(\tau _{T;j;A})$
. If i appears in
$\mathbf {w}_{T;j}$
and
$i+1$
does not appear in
$\mathbf {w}_{T;j}$
, then
$i+1$
holds its position in
$\tau _{T;j;A}$
but i is moved to the right in
$\tau _{T;j;A}$
, so
$i \notin \mathrm {Des}(\tau _{T;j;A})$
. Suppose that i does not appear in
$\mathbf {w}_{T;j}$
and
$i+1 = w_{u_k}$
for some
$1 \le k \le l$
, where
$\mathbf {w}_{T;j} = w_{u_1} w_{u_2} \cdots w_{u_l}$
. By the definition of
$\mathbf {w}_{T;j}$
,
$w_{u_{k+1}} < i$
and appears strictly left of i if
$k < l$
, and
$i \in T(\mathtt {S}_{k_0})$
if
$k = l$
. Thus,
$i \notin \mathrm {Des}(\tau _{T;j;A})$
.
Case 2:
$\pi _i \cdot T = 0$
. We claim that
$\pi _i \cdot {\boldsymbol {\tau }}_{T;j} = 0$
for all
$1 \leq j \leq m$
. Fix
$j \in [m]$
. Since
$i, i+1 \in T(\mathtt {S}_0)$
by the shape of T,
$\textsf {end}(\mathbf {w}_{T;j}) \neq i, i+1$
. So we have from the definition of
$\mathtt {A}_{T;j}$
that either
$i, i+1 \notin \mathtt {A}_{T;j}$
or
$i, i+1 \in \mathtt {A}_{T;j}$
. If
$i, i+1 \notin \mathtt {A}_{T;j}$
, then
$i,i+1 \in \tau _{T;j;A}(\mathtt {S}^{\prime }_{k_{-1}})$
for all
$A \in \mathcal {P}(\mathtt {A}_{T;j})$
, so
$\pi _i \cdot {\boldsymbol {\tau }}_{T;j} = 0$
. If
$i, i+1 \in \mathtt {A}_{T;j}$
, then
$\mathcal {P}(\mathtt {A}_{T;j}) = \mathcal {X} \cup \mathcal {Y} \cup \mathcal {Z}$
, where
$$ \begin{align*} \mathcal{X} & := \{ A \in \mathcal{P}(\mathtt{A}_{T;j}) \mid i \in A, \ i+1 \notin A \} \\ \mathcal{Y} & := \{ A \in \mathcal{P}(\mathtt{A}_{T;j}) \mid i \notin A, \ i+1 \in A \} \\ \mathcal{Z} & :=\{ A \in \mathcal{P}(\mathtt{A}_{T;j}) \mid i,i+1 \in A \} \cup \{ A \in \mathcal{P}(\mathtt{A}_{T;j}) \mid i,i+1 \notin A \} \end{align*} $$
Note that
$\pi _i \cdot \tau _{T;j;A} = 0$
for any
$A \in \mathcal {Z}$
. Therefore, the claim can be shown by proving that
$$ \begin{align} \pi_i \left(\sum_{A \in \mathcal{X}} \mathrm{sgn}(A)\tau_{T;j;A} + \sum_{A \in \mathcal{Y}} \mathrm{sgn}(A)\tau_{T;j;A} \right) = 0. \end{align} $$
Let us consider the bijection
$f: \mathcal {X} \rightarrow \mathcal {Y}$
by
$$ \begin{align*} A \mapsto (A\setminus{\{i\}})\cup{\{i+1\}}. \end{align*} $$
Since
$\mathrm {sgn}(A) + \mathrm {sgn}(f(A)) = 0$
and
$\tau _{T;j;f(A)} = s_i \cdot \tau _{T;j;A}$
, we obtain equation (6.12).
Case 3:
$\pi _i \cdot T = s_i \cdot T$
. We claim that
$\pi _i \cdot {\boldsymbol {\tau }}_{T;j} = {\boldsymbol {\tau }}_{(\pi _i \cdot T);j}$
for all
$1 \leq j \leq m$
. Fix
$1 \leq j \leq m$
with
${\boldsymbol {\tau }}_{T;j} \neq 0$
. If
$i+1 \notin T(\mathtt {S}_{k_0})$
, then
$\textsf {end}(\mathbf {w}_{T;j}) = \textsf {end}(\mathbf {w}_{\pi _i \cdot T;j})$
and
$\mathtt {A}_{T;j} = \mathtt {A}_{(\pi _i \cdot T);j}$
, so
$\mathcal {P}(\mathtt {A}_{T;j}) = \mathcal {P}(\mathtt {A}_{(\pi _i \cdot T);j})$
. This implies that
$$ \begin{align*} \pi_i \cdot {\boldsymbol{\tau}}_{T;j} = \pi_i \left(\sum_{A\in \mathcal{P}(\mathtt{A}_{T;j})} \mathrm{sgn}(A) \tau_{T;j;A}\right) = \sum_{A\in \mathcal{P}(\mathtt{A}_{\pi_i \cdot T;j})} \mathrm{sgn}(A) \tau_{\pi_i \cdot T;j;A} = {\boldsymbol{\tau}}_{(\pi_i\cdot T);j}. \end{align*} $$
Let us assume that
$i+1 \in T(\mathtt {S}_{k_0})$
. First, we consider the case where
$\textsf {end}(\mathbf {w}_{T;j}) = i$
. Combining the assumption
${\boldsymbol {\tau }}_{T;j} \neq 0$
with equation (6.6) yields that
$T^1_{m+k_j-1}> i$
. In addition, for any
$A \in \mathcal {P}(\mathtt {A}_{T;j})$
with
$i+1 \in A$
, we have
$\pi _i \cdot \tau _{T;j;A} = 0$
. Therefore,
$$ \begin{align} \pi_i \cdot {\boldsymbol{\tau}}_{T;j} = \sum_{\substack{A \in \mathcal{P}(\mathtt{A}_{T;j}) \\ i+1 \notin A} } \mathrm{sgn}(A) \ \pi_i \cdot \tau_{T;j;A}. \end{align} $$
On the other hand, since
$\textsf {end}(\mathbf {w}_{\pi _i \cdot T;j}) = i+1$
, we have
$$\begin{align*}\mathcal{P}(\mathtt{A}_{\pi_i \cdot T;j}) = \{A \in \mathcal{P}(\mathtt{A}_{T;j}) \mid i+1 \notin A\}. \end{align*}$$
This implies that
$$ \begin{align} {\boldsymbol{\tau}}_{\pi_i \cdot T;j} = \sum_{A \in \mathcal{P}(\mathtt{A}_{\pi_i \cdot T;j})} \mathrm{sgn}(A) \tau_{\pi_i \cdot T;j;A} = \sum_{\substack{A \in \mathcal{P}(\mathtt{A}_{T;j}) \\ i+1 \notin A} } \mathrm{sgn}(A) \ \tau_{\pi_i \cdot T;j;A}. \end{align} $$
For any
$A \in \mathcal {P}(\mathtt {A}_{T;j})$
with
$i+1 \notin A$
, one can see that
$\pi _i \cdot \tau _{T;j;A} = \tau _{\pi _i \cdot T;j;A}$
. Combining this equality with the equalities given by equations (6.13) and (6.14), we have
$\pi _i \cdot {\boldsymbol {\tau }}_{T;j} = {\boldsymbol {\tau }}_{\pi _i \cdot T;j}$
.
Next, we consider the case where
$\textsf {end}(\mathbf {w}_{T;j}) \neq i$
. Then one sees that
$$ \begin{align*} \mathtt{A}_{(\pi_i \cdot T);j} = \begin{cases} \mathtt{A}_{T;j} & \text{ if } \textsf{end}(\mathbf{w}_{T;j})> i, \\ (\mathtt{A}_{T;j} \setminus \{i+1\})\cup \{ i\} & \text{ if } \textsf{end}(\mathbf{w}_{T;j}) < i. \end{cases} \end{align*} $$
In the former case, one can see that
$\pi _i \cdot {\boldsymbol {\tau }}_{T;j} = {\boldsymbol {\tau }}_{(\pi _i \cdot T);j}$
by mimicking the proof of the case where
$i+1 \notin T(\mathtt {S}_{k_0})$
. For the latter case, set
$$ \begin{align*} f: \mathcal{P}(\mathtt{A}_{T;j}) \rightarrow \mathcal{P}(\mathtt{A}_{(\pi_i \cdot T);j}), \quad A \mapsto f(A) := \begin{cases} (A \setminus \{i+1 \})\cup \{ i\} & \text{ if } i+1 \in A, \\ A & \text{ otherwise.} \end{cases} \end{align*} $$
It is clear that f is bijective. Moreover, since
$\mathrm {sgn}(A) = \mathrm {sgn}(f(A))$
and
$\pi _i \cdot \tau _{T;j;A} = \tau _{(\pi _i\cdot T);j;f(A)}$
, it follows that
$$\begin{align*}\pi_i \cdot {\boldsymbol{\tau}}_{T;j} =\sum_{A \in \mathcal{P}(\mathtt{A}_{T;j})} \mathrm{sgn} (A) \pi_i \cdot \tau_{T;j;A} =\sum_{f(A) \in \mathcal{P}(\mathtt{A}_{(\pi_i \cdot T);j})} \mathrm{sgn} (f(A)) \tau_{(\pi_i\cdot T);j;f(A)} = {\boldsymbol{\tau}}_{(\pi_i \cdot T);j}. \end{align*}$$
(b) Let us show
$\ker (\partial ^1) \supseteq \epsilon (\mathcal {V}_{\alpha })$
. Recall that
$$ \begin{align*} \epsilon(\mathcal{V}_{\alpha}) = \mathbb C \{ T \in \mathrm{SRT}(\underline{{\boldsymbol{\unicode{x3b1}}}}) \mid T_j^{1+\delta_{j,m}}> T^1_{m+k_j-1} \text{ for all } 1\leq j \leq m \}. \end{align*} $$
Therefore, it suffices to show that
$$ \begin{align*}\ker(\partial^1) \supseteq \{ T \in \mathrm{SRT}(\underline{{\boldsymbol{\unicode{x3b1}}}}) \mid T_j^{1+\delta_{j,m}}> T^1_{m+k_j-1} \text{ for all } 1\leq j \leq m \}. \end{align*} $$
Let
$T \in \{ T \in \mathrm {SRT}(\underline {{\boldsymbol {\unicode{x3b1} }}}) \mid T_j^{1+\delta _{j,m}}> T^1_{m+k_j-1} \text { for all } 1\leq j \leq m \}$
. For every
$1\leq j \leq m$
, there exists
$j'>j$
such that
$\textsf {end}(\mathbf {w}_{T;j}) = T_{j'}^{1+\delta _{j',m}}$
. By definition, one has
$$ \begin{align*} T_{j'}^{1+\delta_{j',m}}> T^1_{m+k_{j'}-1} > T^1_{m+k_{j}-1}, \end{align*} $$
so
$\mathcal {P}(\mathtt {A}_{T;j}) = \emptyset $
. By definition,
${\boldsymbol {\tau }}_{T;j} = 0$
, and thus
$T \in \ker (\partial ^1)$
.
Let us show
$\ker (\partial ^1) \subseteq \epsilon (\mathcal {V}_{\alpha })$
. Suppose that there exists
$x \in \ker (\partial ^1) \setminus \epsilon (\mathcal {V}_{\alpha })$
. Let
$x = \sum _{T \in \mathrm {SRT}(\underline {{\boldsymbol {\unicode{x3b1} }}})} c_T T$
with
$c_T \in \mathbb C$
. Since
$\partial ^1(T) = 0$
for all T satisfying that
$T_j^{1+\delta _{j,m}}> T^1_{m+k_j-1}~(1\leq j \leq m)$
, all Ts in the expansion of x are contained in
$\Theta (\mathcal {V}_{\alpha })$
(see equation (4.1)). Define
$$\begin{align*}\textsf{supp}(x) := \{T \in \Theta(\mathcal{V}_{\alpha}) \mid c_T \neq 0\} \end{align*}$$
and choose any tableau U in
$\textsf {supp}(x)$
such that
$\mathbf {w}(U)$
is maximal in
$\{\mathbf {w}(T): T \in \textsf {supp}(x)\}$
with respect to the Bruhat order. Let
$$ \begin{align*} J & := \{j \in [m] \mid \mathcal{P}(\mathtt{A}_{U;j}) \neq \emptyset \} \text{ and}\\ \tau_0 &:= \tau_{U;\max(J);A^1_{U; \max(J)}}. \end{align*} $$
It should be noted that J is nonempty because
$U \in \Theta (\mathcal {V}_{\alpha })$
, and the coefficient of
$\tau _0$
is nonzero in the expansion of
$\partial ^1(U)$
in terms of
$\bigcup _{1 \le j \le m} \mathrm {SRT}(\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)})$
. Note that
$\partial ^1(x) = \partial ^1(c_U U) + \partial ^1(x - c_U U)$
and
$$ \begin{align*} \partial^1(x - c_U U) & = \sum_{T \in \textsf{supp}(x) \setminus \{U\}} c_T \left( \sum_{1\le j \le m} {\boldsymbol{\tau}}_{T;j} \right) \\ & = \sum_{T \in \textsf{supp}(x) \setminus \{U\}} c_T \left( \sum_{1\le j \le m} \sum_{A \in \mathcal{P}(\mathtt{A}_{T;j})} \mathrm{sgn}(A) \tau_{T;j;A} \right). \end{align*} $$
We claim that there is no triple
$(T,j,A)$
with
$T \in \textsf {supp}(x) \setminus \{U\}$
,
$1\le j \le m$
and
$A \in \mathcal {P}(\mathtt {A}_{T;j})$
such that
$\tau _{T;j;A} = \tau _0$
. Suppose not: that is,
$\tau _0 = \tau _{T;j;A}$
for some
$(T,j,A)$
. Comparing the shapes of
$\tau _0$
and
$\tau _{T;j;A}$
, we see that j must be
$\max (J)$
. Let
$\mathbf {w}(T) = w_1 w_2 \cdots w_n$
. According to the definition of
$\mathbf {w}_{T;\max (J)}$
in equation (4.3), it is a decreasing subword
$w_{u_1} w_{u_2} \cdots w_{u_l}$
of
$\mathbf {w}(T)$
subject to the conditions
$$ \begin{align} w_{u_r} < w_{i} \quad \text{for all } 1 \le r < l \text{ and } u_r < i <u_{r+1}. \end{align} $$
Since
$\tau _{T;\max (J);A} = \tau _0$
, one has that
$$\begin{align*}\mathbf{w}(T) = \mathbf{w}(U) \cdot (u_{1}~u_l) (u_{1}~u_{l-1}) \cdots (u_1~u_2), \end{align*}$$
where
$\mathbf {w}(T), \mathbf {w}(U)$
are viewed as permutations and
$(a~b)$
denotes a transposition. For
$\sigma \in \Sigma _n$
and
$a,b \in [n]$
, it is stated in [Reference Björner and Brenti8, Lemma 2.1.4] that
$\sigma \prec \sigma \cdot (a \ b)$
and
$\ell (\sigma \cdot (a \ b)) = \ell (\sigma ) + 1$
if and only if
$\sigma (a) < \sigma (b)$
and there is no c such that
$\sigma (a) < \sigma (c) < \sigma (b)$
. Here
$\prec $
is the Bruhat order. Combining this with equation (6.15) yields that
$\mathbf {w}(U) \prec \mathbf {w}(T)$
. This contradicts the maximality of U; thus our claim is verified. It tells us that the coefficient of
$\tau _0$
in the expansion of
$\partial ^1(x)$
in terms of
$\bigcup _{1 \le j \le m} \mathrm {SRT}(\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)})$
is nonzero, which is absurd by the assumption that
$x \in \ker (\partial ^1)$
. Consequently, we can conclude that there is no
$x \in \ker (\partial ^1) \setminus \epsilon (\mathcal {V}_{\alpha })$
.
(c) Observe the following
$H_n(0)$
-module isomorphisms:
$$ \begin{align*} \mathrm{soc} \left(\bigoplus_{1 \leq j \leq m}\mathbf{P}_{\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}} \right) & \underset{\text{Theorem~2.3}}{\cong} \bigoplus_{1 \leq j \leq m} \bigoplus_{\beta \in [\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}]} \mathrm{soc}(\mathbf{P}_{\beta}) \cong \bigoplus_{1 \leq j \leq m}\bigoplus_{\beta \in [\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}]} \mathbb C T^{\leftarrow}_{\beta} \\ & \hspace{0.55ex} \underset{\text{Lemma~6.8}}{\cong}\mathbb C \left( \overline{\pi}_{\boldsymbol{w_0}(\beta;j)} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}} \right) \end{align*} $$
Hence our assertion can be verified by showing that
$\overline {\pi }_{\boldsymbol {w_0}(\beta ;j)} \cdot {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}} \in \mathrm {Im}(\overline {\partial ^1})$
for
$1 \le j \le m$
and
$\beta \in [\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}]$
. Let us fix
$j \in [m]$
and
$\beta \in [\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}]$
. To begin with, we note that
$$ \begin{align} \overline{\pi}_{\boldsymbol{w_0}(\beta;j)} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}} = \sum_{\sigma \preceq_L \boldsymbol{w_0}(\beta;j)} (-1)^{\ell(\boldsymbol{w_0}(\beta;j)) - \ell(\sigma)} \pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}. \end{align} $$
According to the definition of
$\boldsymbol {w_0}(\beta ;j)$
, we divide into the following two cases.
Case 1:
$\min (\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}})> \ell (\alpha )$
. For
$\sigma \preceq _L \boldsymbol {w_0}(\beta ;j) = w_0(\widehat {\mathtt {J}}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}})$
, it holds that
$$ \begin{align} \begin{aligned} & T(\sigma)^{1+\delta_{j,m}}_{j} = |\mathtt{S}^{\prime}_{k_{-1}}|+1, \\ & T(\sigma)^1_{m+k_{j}-1}=|\mathtt{S}^{\prime}_{k_{-1}}|+2 \text{ and } \\ & T(\sigma)^{1+\delta_{j',m}}_{j'}> T(\sigma)^1_{m+k_{j'}-1} \qquad \text{ if }1 \leq j' \leq m \text{ and } j'\neq j. \end{aligned} \end{align} $$
Moreover, the definition of
$T(\sigma )$
says that
$$ \begin{align} & \mathcal{P}(\mathtt{A}_{T(\sigma);j}) = \left\{A^1:=\left[|\mathtt{S}^{\prime}_{k_{-1}}|+2,|\mathtt{S}^{\prime}_{k_{-1}}|+|\mathtt{S}^{\prime}_{k_0}|\right]\right\}. \end{align} $$
Putting these together, we can derive the following equalities:
$$ \begin{align} \begin{aligned} \overline{\partial^1}(T(\sigma) + \epsilon(\mathcal{V}_{\alpha})) &= \sum_{1 \leq r \leq m}{\boldsymbol{\tau}}_{T(\sigma);r}\\ &={\boldsymbol{\tau}}_{T(\sigma);j} &\text{(by equation } (6.17))\;\\ &=\tau_{T(\sigma);j;A^1} &\text{(by equation } (6.18)). \end{aligned} \end{align} $$
Since
$\tau _{T(\sigma );j;A^1} = \pi _{\sigma } \cdot \tau _{T(\mathrm {id});j;A^1}$
and
$\tau _{T(\mathrm {id});j;A^1} = {T^{\leftarrow }_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}}$
, we see that
$$ \begin{align} \overline{\partial^1}(T(\sigma) + \epsilon(\mathcal{V}_{\alpha})) = \pi_{\sigma} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}. \end{align} $$
Finally, putting equations (6.16) and (6.20) together yields that
$$ \begin{align*} \overline{\pi}_{\boldsymbol{w_0}(\beta;j)} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}} = \sum_{\sigma \preceq_L \boldsymbol{w_0}(\beta;j)} (-1)^{\ell(\boldsymbol{w_0}(\beta;j)) - \ell(\sigma)} \, \overline{\partial^1}(T(\sigma) + \epsilon(\mathcal{V}_{\alpha})), \end{align*} $$
which verifies the assertion.
Case 2:
$\min (\mathtt {J}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}) \le \ell (\alpha )$
. Let
$\sigma \preceq _L \boldsymbol {w_0}(\beta ;j)$
. Since
$$\begin{align*}\boldsymbol{w_0}(\beta;j) = w_0([\ell(\alpha)];|\mathtt{S}^{\prime}_{k_0}|) \cdot w_0(\widehat{\mathtt{J}}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}) \text{ and }\min(\widehat{\mathtt{J}}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}})> \ell(\alpha) + 1, \end{align*}$$
we can write
$\sigma $
as
$\sigma ' \sigma "$
for some
$\sigma ' \in (\Sigma _{n})_{\widehat {\mathtt {J}}_{\beta ;\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}}$
and
$\sigma " \in (\Sigma _{n})_{[\ell (\alpha )]}^{(|\mathtt {S}^{\prime }_{k_0}|)}$
. Therefore, the right-hand side of equation (6.16) can be rewritten as
$$ \begin{align} \sum_{\sigma \preceq_L \boldsymbol{w_0}(\beta;j)} (-1)^{ \ell( w_0(\widehat{\mathtt{J}}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}})) + \ell( w_0([\ell(\alpha)];|\mathtt{S}^{\prime}_{k_0}|)) -(\ell(\sigma') + \ell(\sigma"))} \pi_{\sigma'} \pi_{\sigma"} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}. \end{align} $$
Since
$\{\sigma \in \Sigma _n \mid \sigma \preceq _L \boldsymbol {w_0}(\beta ;j)\}$
can be decomposed into
$$\begin{align*}\bigsqcup_{\sigma' \in (\Sigma_{n})_{\widehat{\mathtt{J}}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}} \bigsqcup_{\sigma" \in (\Sigma_{n})_{[\ell(\alpha)]}^{(|\mathtt{S}^{\prime}_{k_0}|)}} \{\sigma' \sigma"\}, \end{align*}$$
equation (6.21) can also be rewritten as
$$ \begin{align} \sum_{\sigma' \in (\Sigma_{n})_{\widehat{\mathtt{J}}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}} (-1)^{\mathcal{N}(\sigma')} \pi_{\sigma'} \underbrace{\sum_{\sigma" \in (\Sigma_{n})_{[\ell(\alpha)]}^{(|\mathtt{S}^{\prime}_{k_0}|)}} (-1)^{\mathcal{M}(\sigma")} \pi_{\sigma"} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}}_{(\textsf{P})}. \end{align} $$
Here we are using the notation
$$ \begin{align*} \mathcal{N}(\sigma') := \ell(w_0(\widehat{\mathtt{J}}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}})) - \ell(\sigma') \quad \text{ and } \quad \mathcal{M}(\sigma") := \ell(w_0([\ell(\alpha)];|\mathtt{S}^{\prime}_{k_0}|)) - \ell(\sigma"). \end{align*} $$
Note that
$\ell (\alpha )-|\mathtt {S}^{\prime }_{k_0}|+2 = |\mathtt {S}^{\prime }_{k_{-1}}|+1$
since
$\ell (\alpha )+1 = |\mathtt {S}^{\prime }_{k_0}|+|\mathtt {S}^{\prime }_{k_{-1}}|$
. In view of equations (6.9) and (6.11), we see that the summation
$(\textsf {P})$
in equation (6.22) equals
$$ \begin{align*} \sum_{1 \le u \le |\mathtt{S}^{\prime}_{k_{-1}}|+1} \sum_{\zeta \in \left(\Sigma_{n}\right)_{[u+1,\ell(\alpha)]}^{(|\mathtt{S}^{\prime}_{k_0}|+u-1)}} (-1)^{\mathcal{M}(\zeta \Delta_u)} \pi_{\zeta} \pi_{\Delta_u} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}. \end{align*} $$
For each
$1 \le u \le |\mathtt {S}^{\prime }_{k_{-1}}|+1$
, we claim that
$$ \begin{align*} \sum_{\zeta \in \left(\Sigma_{n}\right)_{[u+1,\ell(\alpha)]}^{(|\mathtt{S}^{\prime}_{k_0}|+u-1)}} (-1)^{\mathcal{M}(\zeta \Delta_u)} \pi_{\zeta \Delta_u} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}} = (-1)^{|\mathtt{S}^{\prime}_{k_{-1}}|-u} \partial^1(T(\Delta_u)), \end{align*} $$
which will give rise to
$$ \begin{align*} \overline{\pi}_{\boldsymbol{w_0}(\beta;j)} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}} \in \mathrm{Im}(\partial^1). \end{align*} $$
The last of the proof will be devoted to the verification of this claim. We fix
$u \in [1,|\mathtt {S}^{\prime }_{k_{-1}}|+1]$
and observe that
$$ \begin{align*} &T(\Delta_u)(\mathtt{S}_{k_0}) =[\ell(\alpha) + 1]\setminus\{u\} \text{ and}\\ &\min \left(T(\Delta_u)(\mathtt{S}_{k_{j'}})\right)> \ell(\alpha) + 1 \quad \text{if } 1 \leq j' \leq m \text{ and } j' \neq j. \end{align*} $$
This implies that
$T(\Delta _u)^{1+\delta _{j',m}}_{j'}> T(\Delta _u)^1_{m+k_{j'}-1}$
, and therefore
$$ \begin{align} \partial^1(T(\Delta_u)) = {\boldsymbol{\tau}}_{T(\Delta_u);j} = \sum_{A \in \mathcal{P}(\mathtt{A}_{T(\Delta_u);j})} \mathrm{sgn}(A) \tau_{T(\Delta_u);j;A}. \end{align} $$
Combining Lemma 6.11 with equation (6.6) shows that the summation given in the last term is nonzero. In what follows, we transform this summation into a form suitable for proving our claim. For this purpose, we need to analyse
$\mathcal {P}(\mathtt {A}_{T(\Delta _u);j})$
. Since
$\mathtt {A}_{T(\Delta _u);j} = [u+1,\ell (\alpha )+1]$
and
$\ell (\alpha )-k_j+1 = |\mathtt {S}^{\prime }_{k_0}| - 1$
, it follows that
$$ \begin{align*} \mathcal{P}(\mathtt{A}_{T(\Delta_u);j})=\binom{[u+1,\ell(\alpha)+1]}{|\mathtt{S}^{\prime}_{k_0}| - 1}. \end{align*} $$
Thus we have the natural bijection
$$\begin{align*}\psi: \mathcal{P}(\mathtt{A}_{T(\Delta_u);j}) \rightarrow (\Sigma_n)^{(|\mathtt{S}^{\prime}_{k_0}|-1)}_{[\ell(\alpha)-u]}, \quad A = \{a_1 < a_2 < \cdots < a_{|\mathtt{S}^{\prime}_{k_0}|-1}\} \mapsto \psi(A), \end{align*}$$
where
$\psi (A)$
denotes the permutation in
$(\Sigma _n)^{(|\mathtt {S}^{\prime }_{k_0}|-1)}_{[\ell (\alpha )-u]}$
such that
$\psi (A)(i) = a_i - u$
for
$1 \leq i \leq |\mathtt {S}^{\prime }_{k_0}|-1$
. Recall that there is a natural right
$\Sigma _{|\mathtt {A}_{T(\Delta _u);j}|}$
-action on
$\mathtt {A}_{T(\Delta _u);j}$
given by equation (4.4). Put
$$ \begin{align*} A^0:=[u+1,u+|\mathtt{S}^{\prime}_{k_0}|-1]. \end{align*} $$
Since
$|\mathtt {A}_{T(\Delta _u);j}| = \ell (\alpha ) - u + 1$
, we may identify
$\Sigma _{|\mathtt {A}_{T(\Delta _u);j}|}$
with
$(\Sigma _n)_{[\ell (\alpha )-u]}$
. Note that
$\psi (A)$
is the unique permutation in
$(\Sigma _n)^{(|\mathtt {S}^{\prime }_{k_0}| - 1)}_{[\ell (\alpha )-u]}$
that gives
$A^0$
when acting on A: that is,
$A \cdot \psi (A) = A^0$
. Since
$$\begin{align*}A^0 \cdot \psi(A)^{-1} = \left(A^1_{T(\Delta_u);j}\cdot w_0([\ell(\alpha)-u];|\mathtt{S}^{\prime}_{k_0}|-1)^{-1}\right) \cdot \psi(A)^{-1}, \end{align*}$$
we have that
$$ \begin{align*} \mathrm{sgn}(A) = (-1)^{\ell(w_0([\ell(\alpha)-u];|\mathtt{S}^{\prime}_{k_0}|-1)) - \ell(\psi(A))}. \end{align*} $$
Applying this identity to equation (6.23) yields that
$$ \begin{align} \partial^1(T(\Delta_u)) & = \sum_{A \in \mathcal{P}(\mathtt{A}_{T(\Delta_u);j})} (-1)^{\ell(w_0([\ell(\alpha)-u];|\mathtt{S}^{\prime}_{k_0}|-1)) -\ \ell(\psi(A))} \tau_{T(\Delta_u);j;A}. \end{align} $$
Consider the bijection
$$ \begin{align*}{\theta}_u: (\Sigma_n)^{(|\mathtt{S}^{\prime}_{k_0}| - 1)}_{[\ell(\alpha) - u]} \rightarrow (\Sigma_n)^{(|\mathtt{S}^{\prime}_{k_0}|-1+u)}_{[u+1,\ell(\alpha)]}, \quad s_i \mapsto s_{i + u}. \end{align*} $$
From the constructions of
$T(\Delta _u)$
and
$\tau _{T(\Delta _u);j;A^0}$
, we can derive the identities
$$ \begin{align} \begin{aligned} \tau_{T(\Delta_u);j;A} = \tau_{T(\Delta_u);j;(A^0\cdot \psi(A)^{-1})} = \pi_{{\theta}_u(\psi(A))} \cdot \tau_{T(\Delta_u);j;A^0} = \pi_{{\theta}_u(\psi(A))} \pi_{\Delta_u} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}. \end{aligned} \end{align} $$
As a consequence,
$$ \begin{align*} \partial^1(T(\Delta_u)) & \overset{(6.24)}{=} \sum_{A \in \mathcal{P}(\mathtt{A}_{T(\Delta_u);j})} (-1)^{\ell( w_0([\ell(\alpha)-u];|\mathtt{S}^{\prime}_{k_0}|-1) ) -\ \ell(\psi(A))} \tau_{T(\Delta_u);j;A} \\ & \overset{(6.25)}{=} \sum_{A \in \mathcal{P}(\mathtt{A}_{T(\Delta_u);j})} (-1)^{\ell( w_0([\ell(\alpha)-u];|\mathtt{S}^{\prime}_{k_0}|-1) )-\ell({\theta}_u(\psi(A)))} \pi_{{\theta}_u(\psi(A))}\pi_{\Delta_u} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}. \end{align*} $$
Making use of the bijection
${\theta }_u \circ \psi : \mathcal {P}(\mathtt {A}_{T(\Delta _u);j}) \rightarrow (\Sigma _n)^{(|\mathtt {S}^{\prime }_{k_0}|-1+u)}_{[u+1,\ell (\alpha )]}$
, we can rewrite the second summation as
$$ \begin{align} \begin{aligned} \sum_{\xi \in (\Sigma_n)^{(|\mathtt{S}^{\prime}_{k_0}|-1+u)}_{[u+1,\ell(\alpha)]}} (-1)^{\ell( w_0([\ell(\alpha)-u];|\mathtt{S}^{\prime}_{k_0}|-1) )-\ell(\zeta)} \pi_{\zeta} \pi_{\Delta_u} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}. \end{aligned} \end{align} $$
Note that
$$ \begin{align*} \ell\left( w_0([\ell(\alpha)-u];|\mathtt{S}^{\prime}_{k_0}|-1) \right) -\ell(\zeta) &=(|\mathtt{S}^{\prime}_{k_0}|-1)(\ell(\alpha)-u-|\mathtt{S}^{\prime}_{k_0}|+1) - \ell(\zeta)\\ &=(|\mathtt{S}^{\prime}_{k_0}|-1)(|\mathtt{S}^{\prime}_{k_{-1}}|-u) - \ell(\zeta)\\ &= \mathcal{M}(\zeta\Delta_u) - |\mathtt{S}^{\prime}_{k_{-1}}|+u. \end{align*} $$
By substituting
$\mathcal {M}(\zeta \Delta _u) - |\mathtt {S}^{\prime }_{k_{-1}}|+u$
for
$\ell \left ( w_0([\ell (\alpha )-u];|\mathtt {S}^{\prime }_{k_0}|-1)\right ) -\ell (\zeta )$
in equation (6.26), we finally obtain that
$$\begin{align*}\partial^1(T(\Delta_u)) = (-1)^{|\mathtt{S}^{\prime}_{k_{-1}}| - u} \sum_{\zeta \in (\Sigma_n)^{(|\mathtt{S}^{\prime}_{k_0}|-1+u)}_{[u+1,\ell(\alpha)]}} (-1)^{\mathcal{M}(\zeta\Delta_u)} \pi_{\zeta} \pi_{\Delta_u} \cdot {T^{\leftarrow}_{\beta;\underline{{\boldsymbol{\unicode{x3b1}}}}_{(j)}}}, \end{align*}$$
as required.
(d) It is well known that
$$\begin{align*}\mathrm{Ext}_{H_n(0)}^1(\mathbf{F}_{\beta},\mathcal{V}_{\alpha})=\mathrm{Hom}_{H_n(0)}(\mathbf{F}_{\beta}, \Omega^{-1}(\mathcal{V}_{\alpha}))\end{align*}$$
(see [Reference Benson3, Corollary 2.5.4]). This immediately yields that
$$\begin{align*}\dim\mathrm{Ext}_{H_n(0)}^1(\mathbf{F}_{\beta},\mathcal{V}_{\alpha})= [\mathrm{soc}(\Omega^{-1}(\mathcal{V}_{\alpha})):\mathbf{F}_{\beta}]. \end{align*}$$
By (c), one sees that
$\mathrm {soc}(\Omega ^{-1}(\mathcal {V}_{\alpha }))$
equals the socle of
$\bigoplus _{1 \leq j \leq m} \mathbf {P}_{\underline {{\boldsymbol {\unicode{x3b1} }}}_{(j)}}$
. So we are done.
7 Further avenues
(a) For each
$\alpha \models n$
, let
be a minimal projective presentation of
$\mathbf {F}_{\alpha }$
. From [Reference Benson3, Corollary 2.5.4], we know that
$\dim \mathrm {Ext}_{H_n(0)}^1(\mathbf {F}_{\alpha },\mathbf {F}_{\beta })$
counts the multiplicity of
$\mathbf {P}_{\beta }$
in the decomposition of
$P_1$
into indecomposable modules, equivalently,
$$ \begin{align*} P_1 \cong \bigoplus_{\beta \models n} \mathbf{P}_{\beta}^{\dim \mathrm{Ext}^1_{H_n(0)} (\mathbf{F}_{\alpha},\mathbf{F}_{\beta})}. \end{align*} $$
This dimension has been computed in [Reference Duchamp, Hivert and Thibon14, Section 4] and [Reference Fayers16, Theorem 5.1]. However, to the best of the authors’ knowledge, no description for
$\partial _1$
is available yet. It would be nice to find an explicit description of
$\partial _1$
, especially in a combinatorial manner. If this is done successfully, by taking an anti-automorphism twist introduced in [Reference Jung, Kim, Lee and Oh21, Section 3.4] to equation (7.1), we can also derive a minimal injective presentation for
$\mathbf {F}_{\alpha }$
.
(b) Besides dual immaculate functions, the problem of constructing
$H_n(0)$
-modules has been considered for the following quasisymmetric functions: the quasisymmetric Schur functions in [Reference Tewari and van Willigenburg27, Reference Tewari and van Willigenburg28], the extended Schur functions in [Reference Searles26], the Young row-strict quasisymmetric Schur functions in [Reference Bardwell and Searles2], the Young quasisymmetric Schur functions in [Reference Choi, Kim, Nam and Oh12] and the images of all these quasisymmetric functions under certain involutions on
$\mathrm {QSym}$
in [Reference Jung, Kim, Lee and Oh21]. Although these modules are built in a very similar way, their homological properties have not been well studied. The study of their projective and injective presentations will be pursued in the near future with appropriate modifications to the method used in this paper.
(c) By virtue of Lemma 5.2 and Lemma 5.3, we have a combinatorial description for
$\dim \mathrm {Hom}_{H_n(0)}(\mathbf{P}_{\alpha }, \mathcal {V}_{\beta })$
. However, no similar one is known for
$\dim \mathrm {Hom}_{H_n(0)}(\mathcal {V}_{\alpha }, \mathcal {V}_{\beta })$
except when
$\beta \le _l \alpha $
. It would be interesting to find such a description that holds for all
$\alpha , \beta \models n$
.
Acknowledgements
The authors are grateful to the anonymous referees for their careful readings of the manuscript and valuable advice. And the authors would like to thank So-Yeon Lee for helping with computer programming. This work benefited from computations using SageMath.
Conflicts of Interest
None.
Funding statement
The first author was supported by a National Research Foundation of Korea (NRF) grant funded by the Korean government (No. NRF-2019R1C1C1010668 and No. NRF-2020R1A5A1016126). The second author was supported by an NRF grant funded by the Korean Government (No. NRF-2019R1A2C4069647 and No. NRF-2020R1A5A1016126). The third author was supported by the Basic Science Research Program through the NRF, funded by the Ministry of Education (No. NRF-2019R1I1A1A01062658). The fourth author was supported by an NRF grant funded by the Korean Government (No. NRF-2020R1F1A1A01071055).
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